PROGRAM 35th IEEE PHOTOVOLTAIC SPECIALISTS CONFERENCE

PROGRAM35th IEEE

PHOTOVOLTAICSPECIALISTS CONFERENCE

Hawaiian Convention CenterHonolulu, Hawai’i

June 20-25, 2010

35thPHO

TOVOLTAIC SPECIALISTS CONFEREN

CE

Honolulu, Hawaii •

IEEE

June 20-25, 2010

35th IEEE PHOTOVOLTAIC SPECIALISTS CONFERENCE

MARK YOUR CALENDARS

September 6-10, 2010, Valencia, Spain WCPEC -5, 5th World Conference On Photovoltaic Energy Conversion ( 25th European Photovoltaic Solar Energy

Conference and Exhibition, 20th Asia/Pacific PV Science and Engineering Conference, 36th US

IEEE Photovoltaic Specialists Conference)

June 19-24, 2011, Seattle, Washington37th IEEE Photovoltaic Specialists Conference

June 3-8, 2012, Austin, Texas38th IEEE Photovoltaic Specialists Conference

JUNE 20-25, 2010 • HONOLULU, HAWAI’I35th IEEE PHOTOVOLTAIC SPECIALISTS CONFERENCE

1

35th IEEE PHOTOVOLTAICSPECIALISTS CONFERENCE

CHAIRMAN’S MESSAGE 2GENERAL INFORMATION 4VENUE & POSTER HALL MAPS 8WILLIAM R. CHERRY AWARD 14TUTORIAL PROGRAM 18SOCIAL PROGRAM 22COMMITTEES 28EXHIBITION & SPONSORSHIP 36TUTORIAL SCHEDULE - JUNE 20 46INSTRUCTIONS TO ORAL PRESENTERS 48INSTRUCTIONS TO POSTER PRESENTERS

51

TECHNICAL PROGRAM 53AREA PROGRAM SUMMARIES 57MONDAY - JUNE 21 67TUESDAY - JUNE 22 81WEDNESDAY - JUNE 23 91THURSDAY - JUNE 24 101FRIDAY - JUNE 25 120POSTERS TUESDAY - JUNE 22 133POSTERS WEDNESDAY - JUNE 23 164POSTERS THURSDAY - JUNE 24 191AUTHOR INDEX 205

TA

BLE O

F C

ON

TEN

TS

35thPHO

TOVOLTAIC SPECIALISTS CONFEREN

CE

Honolulu, Hawaii •

IEEE

June 20-25, 2010

2


CHAIRMAN’S MESSAGE

Aloha, As General Chair, I welcome you to the 35th IEEE Photovoltaic Specialist Conference. With this conference, we continue the PV Specialists Conference’s role as the premier technical conference covering all aspects of PV technology from basic material science to installed system performance. We also continue our Industrial Exhibition that brings our PV scientist and engineers together with the PV industry. Set against the backdrop of tremendous progress in renewable energy initiatives ongoing in Hawaii and the beautiful location of Waikiki, this is THE conference for Photovoltaics in 2010, and I am glad that you are here. I want to extend a special Aloha to our students. I am committed to maximizing student participation in the conference, organized by Seth Hubbard, to highlight the importance of our student body to the continued health and vitality of our PV community. I often learn the most from the students attending the conference, and I certainly have the most fun when hanging with the students. If you are student, thanks for being here – enjoy yourself and bring as much PV knowledge as you can back home with you. The central pillar of our conference, the Technical Program, continues our record setting growth with over 900 technical presentations this year. With such a huge depth and breadth of technical content organized by our techical program chair Richard King, we have the welcome challenge of taking it all in within the short four and half days of the conference. Since it is likely that you will not be able to attend all the presentations that you would like to, remember that the manuscripts will be available for download from the conference website after the conference. Also, all posters will be on display throughout the Exhibit Hall hours so that you can stop by at your convenience if you miss the stated session time. Be sure to focus attention on the poster sessions this year, as with over 700 hundred posters, we have made them the central point of the technical program this year. Take a special look at the Auxiliary Program organized by John Brenner as well, since we are holding a full set of programs in parallel with the Technical Sessions that address broader issues within the Photovoltaic Community. These programs will give us a broad perspective of the PV community discussing

CH

AIR

MA

N’S

MES

SA

GE

JUNE 20-25, 2010 • HONOLULU, HAWAI’I

3


topics ranging from methods to accelerate the transition of new technology from research through production and into the market to role of women in PV research and development to symposia discussing real-world impediments to PV grid integration that specifically benefit from our location in Hawaii. The Exhibit Hall is filled with companies especially interesting to us PV Specialists thanks to the leadership of John Martin, as we have created a focus on measurement and characterization equipment manufacturers to compliment the solar cell and array technology manufacturers. Be sure to attend the welcome reception Monday night and return often during the week. As much as I do not want to tempt you away from the Convention Center, our Social Program Chair, Patricia Walters, has done an outstanding job of designing an awesome social program. Continuing with our theme of the Photovoltaic Specialist Conference enhancing our Photovoltaic Specialist Community, our goal is to create relationships on a social as well as professional level amongst our attendees, families, and companions. From Welcome Reception on Monday, the Cherry Award Reception on Tuesday, and the Conference Banquet on Thursday to the daily sightseeing tours to places like the Dole Plantation, North Shore, and Pearl Harbor, the social program is going to be a blast. I want to say a huge “Mahalo” to everyone on my conference committee that made this conference happen. As you are enjoying yourself here in Hawaii, please take a moment to stop anyone on the committee to thank them for the time and dedication to the conference. Robert J. Walters PVSC 35 Conference Chair

CH

AIR

MA

N’S

MES

SA

GE

4


GENERAL INFORMATION

DATESThe 35th IEEE Photovoltaic Specialists Conference begins Sunday June 20th with a day of tutorials. The technical program begins Monday June 21st and concludes June 25th, 2010.

CONFERENCE VENUEHawaii Convention Center1801 Kalakaua AvenueHonolulu, HI 96815-1513(808) 943-3500www.hawaiiconvention.com

REGISTRATION INFORMATIONName badges and final programs will be distributed at the Registration Desk. The Registration Desk will be open during the following hours:

Saturday • 4:00 PM - 8:00 PM Sunday - Tuesday • 7:00 AM - 8:00 PM Wednesday - Thursday • 8:00 AM - 5:00 PM Friday • 8:00 AM - 12:00 PM

SPEAKER READY ROOMThe speaker ready room will be available to all oral presenters to both preview and edit your presentations if necessary. The speaker ready room is located in room 318A will be open during the following hours:

Sunday • 12:00 PM- 5:00 PM Monday-Thursday • 7:00 AM- 5:00 PM Friday • 7:00 AM- 10:00 AM NO PHOTOGRAPHY POLICY The Organizing Committee has decided that photography is not allowed except for official conference photographers.

CONFERENCE MESSAGE CENTERAn information and message center will be located in the registration area. The message center may be reached by calling 808-792-6520.

AUTHOR’S BREAKFASTAll poster and oral presenters are required to attend the Author’s Breakfast at 7:00 AM the morning of (each of) your presentation(s) for instructions, to meet your session chair, and to be sure all your materials have uploaded correctly. Breakfast will be in Room 323 ( Monday,Thursday, Friday) & Ballroom C (Tuesday, Wednesday).

GEN

ER

AL IN

FO

RM

ATIO

N


5


COFFEE BREAKSCoffee and soda breaks will be available each morning and afternoon. Please see below for locations:

AM Breaks Monday - 4th Floor Ballroom Foyer Tuesday - Exhibit Hall Wednesday - Exhibit Hall Thursday - Exhibit Hall Friday - Ala Halawai Concourse

PM Breaks Monday - Ala Halawai Concourse Tuesday - Exhibit Hall Wednesday - Exhibit Hall Thursday - Ala Halawai Concourse

EXHIBITSThe exhibit hall is located on level 1 of the convention center and will be open during the following hours:

June 21 • 5:30PM - 8:30PM (Opening Reception) June 22 • 10:00 AM - 5:00 PM (Public 1:30-5:00 PM) June 23 • 10:00 AM - 5:00 PM June 24 • 10:00 AM - 3:00 PM

SHUTTLE SCHEDULEHilton Hawaiian Village – Hawaii Convention Center (Shuttles will leave approximately every 30 minutes from the Hilton Hawaiian Village and the Hawaii Convention Center )

Day From ToMonday 6:30 AM

3:30 PM9:30 AM9:30 PM

Tuesday 6:30 AM3:30 PM

9:30 AM6:30 PM

Wednesday 6:30 AM3:30 PM

9:30 AM6:30 PM

Thursday 6:30 AM3:30 PM

9:30 AM6:30 PM

Friday 6:30 AM 1:30 PM

GEN

ER

AL I

NFO

RM

ATIO

N

6


IEEE ELECTRON DEVICES SOCIETY - MEMBERSHIP PROMOTIONS FOR PVSC ATTENDEES

PVSC registrants will be able to take advantage of EDS membership offers only available for the duration of the conference. Simply check YES on the conference registration form for the membership you qualify for and you will receive FREE half-year IEEE EDS membership. Review the offers below for details:

Affiliate Member: If you are a member of another scientific/technical society, you will receive FREE EDS membership for one-half year. By joining IEEE as an affiliate member you enjoy all the benefits of being an EDS member.

Student: If you registered and paid for the conference at the student, non-member rate you will receive one half-year of FREE IEEE and EDS.

Current IEEE Member: FREE EDS membership for one half-year will be offered to any IEEE member attending the PVSC who is NOT currently a member of the Electron Devices Society (EDS). Please note if you are currently a member of EDS, you cannot use this offer to renew your membership.

Non-IEEE Member: If you registered and paid for the conference as a non-member, you will be receiving a Credit Voucher in your registration bag, worth $25 towards a half-year of IEEE membership and Free EDS membership for one half-year.

EDS credit vouchers will also be available at the EDS Membership Booth, which will be located in the PVSC Registration Area.

THE HIGH SCHOOL PHOTOVOLTAIC COMPETITION

For the Photovoltaic Design Competition, the students are asked to work on their projects (under the supervision or mentoring of a faculty member, for example) and display their project at the Conference in June, 2010. The design projects must demonstrate the use of photovoltaics in a practical application, using only photovoltaics as the power source for the project. Awards will be made for the top achievements Tuesday evening before the Cherry Reception.

GEN

ER

AL IN

FO

RM

ATIO

N


7


AD

VER

TIS

EM

EN

T

The Solar Energy Industries Association represents more than 1,000 companies working in every facet of the

solar energy industry.

No matter your role in the solar industry, SEIA membership will provide you with the critical information,

advocacy, education, and networking opportunities to help you grow your business while ensuring the long-term

success of the solar energy industry.

SEIA member benefits include:

• Discounts on insurance with our group program

• Exclusive access to the SEIA tax manual

• Participation in our monthly webinar series

• Connect with other companies in the Business-to-Business network

• Savings at Solar Power International and PV America

Join SEIA today! www.seia.org

Questions? Contact us: [email protected]

8


VEN

UE M

AP

- TH

IRD

FLO

OR

316A-B-C† 12,090 1123 86' 140' 17' 1,193 1,188 800 600316A† 4,252 395 86' 49' 17' 417 414 260 180316B† 3,526 328 86' 41' 17' 358 342 208 180316C† 4,252 395 86' 49' 17' 417 414 260 180317A-B 3,901 362 45' 86' 17' 395 378 224 180317A 1,946 181 45' 43' 17' 197 171 104 90317B 1,937 180 45' 42' 17' 197 171 104 90318A-B 2,937 273 45' 64' 17' 298 261 168 120318A 1,463 136 45' 32' 17' 149 133 72 60318B 1,459 136 45' 32' 17' 149 133 72 60319A-B 3,422 318 56' 60' 17' 348 280 160 150319A 1,704 158 56' 30' 17' 176 132 92 60319B 1,701 158 56' 30' 17' 173 132 92 60320-Theater 4,218 N/A N/A N/A N/A 320 320 320 N/A

Existing drop down Screen: 12'w x 10'h, 54' from projection booth to screen

321A-B 2,219 206 43' 51' 17' 223 192 120 100321A 1,105 103 43' 25' 17' 119 108 48 30321B 1,101 102 43' 25' 17' 119 108 48 30322A-B 1,757 163 28' 60' 17' 174 130 72 70322A 874 81 28' 30' 17' 90 63 32 30322B 874 81 28' 30' 17' 90 70 32 30323A-B-C† 6,433 598 60' 105' 17' 644 624 360 280323A† 1,982 184 60' 32' 17' 260 182 108 80323B† 1,991 185 57' 39' 17' 245 234 144 90323C† 1,994 185 60' 32' 17' 200 182 108 80324 2,035 189 60' 35' 17' 234 195 108 110325A-B 2,371 220 39' 60' 17' 230 182 120 110325A 1,180 110 39' 30' 17' 115 113 60 50325B 1,180 110 39' 30' 17' 115 100 54 50326A-B 1,701 158 37' 45' 17' 154 140 84 60326A-Exec. Mtg. 847 79 37' 22' 17' 77 70 36 30326B-Exec. Mtg. 823 76 37' 21' 17' 77 70 32 30327-Exec. Mtg. 1,599 149 36' 44' 17' 153 140 84 70328-Exec. Mtg. 1,591 148 36' 43' 17' 159 140 84 70

* Please note that room capacities may vary depending on the audio visual and staging requirementsof your program. See your Event Manager for a customized floor plan of your event.

† Recommended maximum capacities allowing for podium, head table and 8' x 12' staging (Rooms 311-316 and 323).

MEET ING ROOMS ~ TH IRD F LOOR

MEET ING ROOMS ~ TH IRD F LOOR ROOM TOTAL TOTAL DIMENSIONS CAPACITIES*

Sq. Ft. Sq. Meters L W H Max. Theater Class Banquet

301A-B 3,600 336 48' 75' 17' 354 324 200 160301A 1,536 144 48' 32' 17' 152 147 88 60301B 2,064 192 48' 43' 17' 202 199 108 90302A-B 1,945 181 36' 53' 17' 206 168 98 80302A-Exec. Mtg. 985 91 36' 27' 17' 103 84 40 40302B-Exec. Mtg. 947 88 36' 26' 17' 103 84 36 30303A-B 1,726 160 41' 41' 17' 166 142 88 60303A 852 79 41' 20' 17' 86 73 44 30303B 863 80 41' 20' 17' 86 77 44 30304A-B 2,615 243 50' 52' 17' 292 258 140 120304A-Exec. Mtg. 1,313 122 50' 26' 17' 146 120 64 70304B-Exec. Mtg. 1,315 122 50' 26' 17' 146 132 64 70305A-B 1,952 181 41' 46' 17' 189 162 112 100305A 806 75 41' 19' 17' 80 72 44 30305B 1,131 105 41' 27' 17' 110 104 44 50306A-B 3,365 313 63' 52' 17' 368 322 192 160306A-Exec. Mtg. 1,675 156 63' 26' 17' 184 150 84 80306B-Exec. Mtg. 1,672 155 63' 26' 17' 184 168 84 80307A-B 1,566 145 41' 37' 17' 151 132 88 80307A 743 69 41' 17' 17' 71 64 24 30307B 807 75 41' 19' 17' 80 72 44 30308A-B 1,994 185 41' 47' 17' 196 180 108 100308A 860 80 41' 20' 17' 86 80 44 30308B 1,119 104 40' 26' 17' 109 102 44 50309 1,539 143 41' 32' 17' 135 117 72 60310-Theater 6,253 N/A N/A N/A N/A 472 472 472 N/A

Existing drop down Screen: 14'w x 12'h, 55' from projection booth to screen311† 6,051 562 86' 70' 17' 610 600 392 300312† 4,432 412 86' 51' 17' 450 437 280 240313A-B-C† 12,096 1,124 86' 140' 17' 1,193 1,188 800 600313A† 4,252 395 86' 49' 17' 417 414 260 180313B† 3,448 320 86' 41' 17' 358 342 208 180313C† 4,252 395 86' 49' 17' 417 414 260 180314† 3,771 350 86' 43' 17' 381 381 224 180315† 4,431 412 86' 51' 17' 450 440 280 240

2020

2020

20

2020

2020

20

2020

20

20

22

22 20

20

20

20

22

2222

2222

22

2020

2020

2020

20

2020

2020

2020

20

22

2222

22

22

2222

2020

2020

2020

20

2020

20

20

2222

22

2222

2020

2020

2020

20

2020

2020

2022

2222

22

2222

22

2020

2020

20

2022

2121

2121

21

2121

21

2121

20

20

21

21

21

20

21

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

2222

2121212121

21

22

22

21

222222222222

2222

22

20

22

22

21

22222222222222

2222

2222

2222

222222 2221

222222 2222

2222222222

212121 2121

222222 2222

2222222222

2120202020

21

22

21

22

20

20

21

2221 21

21

20

2222

21

21

22 2222

2222

22

2121

2222

2222

21

2121

2121

21

20

21

20

20

21

21

2121

22

20

2222

2222

2121

2121

22

2121

21

2020

22

22

22

22

22

22

22

22

22

22

22

22

22

22

21

22

22

22

22

22

2122

2120

20

20

20

20

20

22

21

21

22

22

22

22

20

20

2122

22

20

20

20

20

21

20

20

20

21

2121

22

21212121

212121

22222121

2121

2121

2222

2222

2222

2222

22

2122

2222

21

21

21

2121

21

22

22

2121

21

22

22

22

22

2121

21

2122

21

2122

21

21

21

21

21

21

21

21

21

2121

21

21

21

21

21

21

21

22

21

22

2222

2222

21

2121

21

21

2020

2020

20

212021

2121

2222

22

2222

2222

22

21

2222

2121

2121

21

2121

2121

21

222121

21212121

2021

22

22

22

2222

2222

2222

2222

2222

2222

22

20

20

2121

22

20

2122

2121

2121

2121

2222

2222

2222

22

21

WAI L

ANI WATER

FALL

★

20 20

20 20 20

2020

21 22

22

2221

21

22

20

20

2020

2020

2020

2020

2020

2020

2020

2020

2020

2020

2020

20

2020

2020

2020

2020

2020

2020

2020

2020

2020

20

2020

2020

2020

2020

2020

2020

2020

2020

20

2020

2020

2020

202020

2020

2020

2020

2020

2020

2020

2020

20

20

20

2020

2020

2020

20

20

2020

2020

20

2020

20

22

SmokingArea

VENUE MAP - THIRD FLOOR


9


316A-B-C† 12,090 1123 86' 140' 17' 1,193 1,188 800 600316A† 4,252 395 86' 49' 17' 417 414 260 180316B† 3,526 328 86' 41' 17' 358 342 208 180316C† 4,252 395 86' 49' 17' 417 414 260 180317A-B 3,901 362 45' 86' 17' 395 378 224 180317A 1,946 181 45' 43' 17' 197 171 104 90317B 1,937 180 45' 42' 17' 197 171 104 90318A-B 2,937 273 45' 64' 17' 298 261 168 120318A 1,463 136 45' 32' 17' 149 133 72 60318B 1,459 136 45' 32' 17' 149 133 72 60319A-B 3,422 318 56' 60' 17' 348 280 160 150319A 1,704 158 56' 30' 17' 176 132 92 60319B 1,701 158 56' 30' 17' 173 132 92 60320-Theater 4,218 N/A N/A N/A N/A 320 320 320 N/A

Existing drop down Screen: 12'w x 10'h, 54' from projection booth to screen

321A-B 2,219 206 43' 51' 17' 223 192 120 100321A 1,105 103 43' 25' 17' 119 108 48 30321B 1,101 102 43' 25' 17' 119 108 48 30322A-B 1,757 163 28' 60' 17' 174 130 72 70322A 874 81 28' 30' 17' 90 63 32 30322B 874 81 28' 30' 17' 90 70 32 30323A-B-C† 6,433 598 60' 105' 17' 644 624 360 280323A† 1,982 184 60' 32' 17' 260 182 108 80323B† 1,991 185 57' 39' 17' 245 234 144 90323C† 1,994 185 60' 32' 17' 200 182 108 80324 2,035 189 60' 35' 17' 234 195 108 110325A-B 2,371 220 39' 60' 17' 230 182 120 110325A 1,180 110 39' 30' 17' 115 113 60 50325B 1,180 110 39' 30' 17' 115 100 54 50326A-B 1,701 158 37' 45' 17' 154 140 84 60326A-Exec. Mtg. 847 79 37' 22' 17' 77 70 36 30326B-Exec. Mtg. 823 76 37' 21' 17' 77 70 32 30327-Exec. Mtg. 1,599 149 36' 44' 17' 153 140 84 70328-Exec. Mtg. 1,591 148 36' 43' 17' 159 140 84 70

* Please note that room capacities may vary depending on the audio visual and staging requirementsof your program. See your Event Manager for a customized floor plan of your event.

† Recommended maximum capacities allowing for podium, head table and 8' x 12' staging (Rooms 311-316 and 323).

MEET ING ROOMS ~ TH IRD F LOOR

MEET ING ROOMS ~ TH IRD F LOOR ROOM TOTAL TOTAL DIMENSIONS CAPACITIES*


301A-B 3,600 336 48' 75' 17' 354 324 200 160301A 1,536 144 48' 32' 17' 152 147 88 60301B 2,064 192 48' 43' 17' 202 199 108 90302A-B 1,945 181 36' 53' 17' 206 168 98 80302A-Exec. Mtg. 985 91 36' 27' 17' 103 84 40 40302B-Exec. Mtg. 947 88 36' 26' 17' 103 84 36 30303A-B 1,726 160 41' 41' 17' 166 142 88 60303A 852 79 41' 20' 17' 86 73 44 30303B 863 80 41' 20' 17' 86 77 44 30304A-B 2,615 243 50' 52' 17' 292 258 140 120304A-Exec. Mtg. 1,313 122 50' 26' 17' 146 120 64 70304B-Exec. Mtg. 1,315 122 50' 26' 17' 146 132 64 70305A-B 1,952 181 41' 46' 17' 189 162 112 100305A 806 75 41' 19' 17' 80 72 44 30305B 1,131 105 41' 27' 17' 110 104 44 50306A-B 3,365 313 63' 52' 17' 368 322 192 160306A-Exec. Mtg. 1,675 156 63' 26' 17' 184 150 84 80306B-Exec. Mtg. 1,672 155 63' 26' 17' 184 168 84 80307A-B 1,566 145 41' 37' 17' 151 132 88 80307A 743 69 41' 17' 17' 71 64 24 30307B 807 75 41' 19' 17' 80 72 44 30308A-B 1,994 185 41' 47' 17' 196 180 108 100308A 860 80 41' 20' 17' 86 80 44 30308B 1,119 104 40' 26' 17' 109 102 44 50309 1,539 143 41' 32' 17' 135 117 72 60310-Theater 6,253 N/A N/A N/A N/A 472 472 472 N/A

Existing drop down Screen: 14'w x 12'h, 55' from projection booth to screen311† 6,051 562 86' 70' 17' 610 600 392 300312† 4,432 412 86' 51' 17' 450 437 280 240313A-B-C† 12,096 1,124 86' 140' 17' 1,193 1,188 800 600313A† 4,252 395 86' 49' 17' 417 414 260 180313B† 3,448 320 86' 41' 17' 358 342 208 180313C† 4,252 395 86' 49' 17' 417 414 260 180314† 3,771 350 86' 43' 17' 381 381 224 180315† 4,431 412 86' 51' 17' 450 440 280 240

2020

2020

20

2020

2020

20

2020

20

20

22

22 20

20

20

20

22

2222

2222

22

2020

2020

2020

20

2020

2020

2020

20

22

2222

22

22

2222

2020

2020

2020

20

2020

20

20

2222

22

2222

2020

2020

2020

20

2020

2020

2022

2222

22

2222

22

2020

2020

20

2022

2121

2121

21

2121

21

2121

20

20

21

21

21

20

21

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

22

2222

2121212121

21

22

22

21

222222222222

2222

22

20

22

22

21

22222222222222

2222

2222

2222

222222 2221

222222 2222

2222222222

212121 2121

222222 2222

2222222222

2120202020

21

22

21

22

20

20

21

2221 21

21

20

2222

21

21

22 2222

2222

22

2121

2222

2222

21

2121

2121

21

20

21

20

20

21

21

2121

22

20

2222

2222

2121

2121

22

2121

21

2020

22

22

22

22

22

22

22

22

22

22

22

22

22

22

21

22

22

22

22

22

2122

2120

20

20

20

20

20

22

21

21

22

22

22

22

20

20

2122

22

20

20

20

20

21

20

20

20

21

2121

22

21212121

212121

22222121

2121

2121

2222

2222

2222

2222

22

2122

2222

21

21

21

2121

21

22

22

2121

21

22

22

22

22

2121

21

2122

21

2122

21

21

21

21

21

21

21

21

21

2121

21

21

21

21

21

21

21

22

21

22

2222

2222

21

2121

21

21

2020

2020

20

212021

2121

2222

22

2222

2222

22

21

2222

2121

2121

21

2121

2121

21

222121

21212121

2021

22

22

22

2222

2222

2222

2222

2222

2222

22

20

20

2121

22

20

2122

2121

2121

2121

2222

2222

2222

22

21

WAI L

ANI WATER

FALL

★

20 20

20 20 20

2020

21 22

22

2221

21

22

20

20

2020

2020

2020

2020

2020

2020

2020

2020

2020

2020

2020

20

2020

2020

2020

2020

2020

2020

2020

2020

2020

20

2020

2020

2020

2020

2020

2020

2020

2020

20

2020

2020

2020

202020

2020

2020

2020

2020

2020

2020

2020

20

20

20

2020

2020

2020

20

20

2020

2020

20

2020

20

22

SmokingArea

VEN

UE M

AP

- T

HIR

D F

LO

OR

10


VEN

UE M

AP

- FO

UR

TH

FLO

OR

VENUE MAP - FOURTH FLOOR

ROOM TOTAL TOTAL DIMENSIONS CAPACITIES*


Ballroom ABC 35,259 3,276 155' 227' 25' 5,000 3,709 2,016 2,040

Section A 11,198 1,040 155' 72' 25' 1,575 1,170 664 590

Section B 12,757 1,185 155' 82' 25' 1,850 1,369 768 710

Section C 11,206 1,041 155' 72' 25' 1,575 1,170 664 590

Section AB 24,002 2,230 155' 155' 25' 3,425 2,539 1,596 1,200

Section BC 24,009 2,230 155' 155' 25' 3,425 2,539 1,596 1,200

Ballroom Foyer 20,074 1,865 244' 82' 14' 1,327 N/A N/A N/A

B A L L RO O M S ~ F O U RT H F L O O R

RO O F TO P G A R D E N ~ F O U RT H F L O O RRO O F TO P G A R D E N F E AT U R E S :◆ 2.5 acre open air rooftop garden◆ Tenting available up to 9,984 sq. ft.◆ Floor Load Limit, 100 lbs per net sq. ft.◆ For more information about hosting events

on the rooftop, please refer to the Rooftop

Garden Terrace Reservation Policy in the

Event Planners Handbook

SMOKING AREA


11


ROOM TOTAL TOTAL DIMENSIONS CAPACITIES*


Ballroom ABC 35,259 3,276 155' 227' 25' 5,000 3,709 2,016 2,040

Section A 11,198 1,040 155' 72' 25' 1,575 1,170 664 590

Section B 12,757 1,185 155' 82' 25' 1,850 1,369 768 710

Section C 11,206 1,041 155' 72' 25' 1,575 1,170 664 590

Section AB 24,002 2,230 155' 155' 25' 3,425 2,539 1,596 1,200

Section BC 24,009 2,230 155' 155' 25' 3,425 2,539 1,596 1,200

Ballroom Foyer 20,074 1,865 244' 82' 14' 1,327 N/A N/A N/A

B A L L RO O M S ~ F O U RT H F L O O R

RO O F TO P G A R D E N ~ F O U RT H F L O O RRO O F TO P G A R D E N F E AT U R E S :◆ 2.5 acre open air rooftop garden◆ Tenting available up to 9,984 sq. ft.◆ Floor Load Limit, 100 lbs per net sq. ft.◆ For more information about hosting events

on the rooftop, please refer to the Rooftop

Garden Terrace Reservation Policy in the

Event Planners Handbook

SMOKING AREA

VEN

UE M

AP

- F

OU

RTH

FLO

OR

12


A B C D E F G H I J K L M N O P Q R S T U V W X1 12 23 34 45 56 67 78 89 910 1011 1112 1213 1314 1415 1516 1617 1718 1819 1920 2021 2122 2223 2324 2425 2526 2627 2728 2829 2930 3031 3132 3233 3334 34

VENUE MAP - POSTER HALL

POSTER ISLE

RO

W

Area 1: Fundamentals and New Concepts for Future Technologies Area 2: CIGS and CdTe Thin Film Solar Cells and Related Materials Area 3: III-V and Concentrator Technologies Area 4: Crystalline Silicon Technologies Area 5: Amorphous, Nano, and Film Si Technologies Area 6: Organic Photovoltaics Area 7: Space Technologies Area 8: Advances in Characterization of Photovoltaics Area 9: PV Modules and Terrestrial Systems Area 10: PV Velocity Forum

VEN

UE M

AP

- PO

STER

HA

LL


13


A B C D E F G H I J K L M N O P Q R S T U V W X1 12 23 34 45 56 67 78 89 910 1011 1112 1213 1314 1415 1516 1617 1718 1819 1920 2021 2122 2223 2324 2425 2526 2627 2728 2829 2930 3031 3132 3233 3334 34

POSTER ISLE

RO

W

VEN

UE M

AP

- P

OS

TER

HA

LL

14


WILLIAM R. CHERRY AWARD

This award is named in honor of William R. Cherry, a founder of the photovoltaic community. In the 1950's, he was instrumental in establishing solar cells as the ideal power source for space satellites and for recognizing, advocating, and nurturing the use of photovoltaic systems for terrestrial applications. The William R. Cherry award was instituted in l980, shortly after his death. The purpose of the award is to recognize engineers and scientists who devote a part of their professional life to the advancement of the technology of photovoltaic energy conversion. The nominee must have made significant contributions to the science and/or technology of PV energy conversion, with dissemination by substantial publications and presentations. Professional society activities, promotional and/or organizational efforts and achievements are not considerations in the election for the award.

This award is presented at each IEEE Photovoltaic Specialists Conference. The recipient is selected by the William R Cherry Committee composed of past PVSC conference chairpersons and past recipients of the award. Those nominated for the award do not participate in the process.

To be eligible for the award, the nominee must currently be active in the science and technology of PV conversion. He/she must have been active in the field for an extended period, with expectation of continued activity. Short term activities in the field, and/or single outstanding contributions are not adequate to make a person eligible for the award.

WIL

LIA

M R

. CH

ER

RY

AW

AR

D


15


Please send any nominations for the next William R. Cherry award (37th IEEE PVSC) to:

Dr. Masafumi YamaguchiToyota Technological Institute2-12-1 Hisakata TempakuNagoya 468-8511JAPANTel: +81-52-809-1875Fax: +81-52-809-1879E-mail: [email protected]

The deadline for Cherry Award nominations to be considered for the 37th IEEE PVSC is December 15, 2010.

Previous Cherry Award Recepients

Dr. Paul Rappaport 1980Dr. Joseph L. Loferski 1981Prof. Martin Wolf 1982Dr. Henry W. Brandhorst 1984Mr. Eugene L. Ralph 1985Dr. Charles E. Backus 1987Dr. David E. Carlson 1988Dr. Martin A. Green 1990Mr. Peter A. Iles 1991Dr. Lawrence L. Kazmerski 1993Prof. Yoshihiro Hamakawa 1994Dr. Allen M. Barnett 1996Dr. Adolf Goetzberger 1997Dr. Richard J. Schwartz 1998Dr. Christopher R. Wronski 2000Dr. Richard M. Swanson 2002Dr. Ajeet Rohatgi 2003Dr. Timothy J. Coutts 2005Dr. Antonio Luque 2006Dr. Masafumi Yamaguchi 2008 Dr. Stuart Wenham 2009

WIL

LIA

M R

. C

HER

RY

AW

AR

D

16


THIS YEAR THE WILLIAM R. CHERRY AWARD WILL BE PRESENTED TO:

DR. RICHARD R. KING

Richard R. King was born in Chapel Hill, North Carolina in 1960. Dr. King is currently Principal Scientist responsible for Photovoltaic Cell R&D at Spectrolab, Inc. His research on photovoltaics over the last 25 years has explored high-efficiency solar cells in a number of semiconductor materials systems, from silicon, to the GaInP, GaInAs, and germanium subcells in III-V multijunction cells. Dr. King's solar cell research led the emergence of III-V multijunction concentrator cells as the photovoltaic technology with the highest and most rapidly rising efficiency, helping to enable the recent growth of the concentrator photovoltaics industry, which now primarily uses this type of solar cell.

In his Ph.D. research at Stanford University, Dr. King worked to develop high-efficiency one-sun back-contact silicon solar cells, and his characterization studies of minority-carrier recombination at the doped Si/SiO2 interface are still in use today for high-efficiency silicon solar cell design. At Spectrolab, his research has contributed to understanding of metamorphic III-V materials lattice-mismatched to the growth substrate; group-III sublattice ordering in GaInP; minority-carrier recombination at III-V heterointerfaces; wide-band-gap tunnel junctions; high-efficiency GaInP/GaInAs/Ge triple-junction solar cells; dilute nitride materials such as ~1-eV GaInNAs solar cells; and multijunction solar cells formed by wafer bonding dissimilar materials such as III-V semiconductors and silicon. Dr. King's work has emphasized the juncture between materials science

WIL

LIA

M R

. CH

ER

RY

AW

AR

D


17


and solar cell recombination physics, throwing light on theoretical performance limits, energy generation, and experimental demonstration of future high-efficiency solar cell designs, such as 4-, 5-, and 6-junction solar cells.

At Spectrolab, Dr. King is principal investigator of Spectrolab’s Air Force Research Laboratory Next-Generation Solar Cell (AFRL Next-Gen) program, which led to the demonstration of the first space solar cells with over 30% AM0 efficiency, and developed the technology needed for the last 3 generations of space solar cells. He was principal investigator in charge of high-efficiency terrestrial concentrator cell development in Spectrolab's High Performance Photovoltaics (HiPerf PV) program from the National Renewable Energy Laboratory (NREL), and over the years has built a team of top-notch solar cell researchers at Spectrolab.

Dr. King led Spectrolab's development of III-V multijunction cell structures resulting in new heights in solar cell efficiencies, recognized with R&D 100 awards in 2001 and 2007, and a Scientific American 50 award in 2002. In 2006, this work led to a record 40.7%-efficient metamorphic 3-junction terrestrial concentrator cell, the first solar cell of any type to reach over 40% efficiency. Dr. King and his research team have since produced a 41.6%-efficient 3-junction GaInP/GaInAs/Ge cell, another step in a long series of record solar cell efficiencies. As part of his strong interest in furthering public and scientific awareness of photovoltaics, Dr. King has helped organize a number of international conferences, serving as Program Chair for the 4th International Conference on Solar Concentrators (ICSC-4) in 2007, and the 35th IEEE Photovoltaic Specialists Conference (PVSC-35) in 2010. Dr. King was inducted into the Space Technology Hall of Fame in 2004, and has 12 patents and over 100 publications on photovoltaics and semiconductor device physics.

WIL

LIA

M R

. C

HER

RY

AW

AR

D

18


TUTORIAL PROGRAM

AM TUTORIALS (8:30 AM – 12:00 PM)

1. Photovoltaics 101

Instructor - Dr. Fred Newman, Staff Scientist at Emcore Photovoltaics and Adjunct Professor at University of New MexicoSynopsis - An introductory tutorial in photovoltaic principles and devices. Basic semiconductor physics will be covered, with an emphasis on semiconductor junctions. The basic current-voltage relationship for a solar cell will be derived. Performance optimization and various loss mechanisms for the general solar cell will be discussed. The course is designed for those with a background in physics, chemistry, and/or engineering, but not yet having a strong background in semiconductor devices.

2. Silicon Solar Cell Technology

Instructor - Dr. Ron Sinton, Sinton InstrumentsSynopsis - This tutorial will look at various aspects of crystalline silicon technologies, from the silicon feedstock, through crystallization, sawing, and solar cell production. The interactions between the various stages from feedstock through the cell manufacturing process will be discussed. An emphasis will be placed on device physics as well as test and measurement strategies that are used to optimize the cell design and process optimization.

3. High Efficiency Multi-junction Cell Technology

Instructor - Dr. Frank Dimroth, Fraunhofer Institute for Solar EnergySynopsis - The tutorial will give a general introduction to the field of high efficiency multi-junction solar cells for the use in space and terrestrial concentrator systems. It will start from basic theoretical considerations and explain the benefits of using several pn-junctions (mainly from III-V compound semiconductors) to convert the broad solar spectrum into electricity. Some historic background of the technology development will be given. Specific requirements for the use of modern multi-junction solar cells in space and under concentrated sunlight on earth will be discussed. The most successful solar cell structures leading to > 40 % efficiency will be introduced and next generation concepts including ultra thin (~10 µm) devices will be presented. Further topics cover: manufacturing aspects, process technology, operation of tunnel diodes, theoretical simulation and solar cell characterization.

TU

TO

RIA

L P

RO

GR

AM


19


4. PV System Installation, Grid Integration, Permitting, etc.

Instructor - Bill Brooks PE, Brooks Engineering LLC. Over 5,000 installers and 5,000 inspectors have taken Mr. Brooks classes.Synopsis - This workshop will help the audience better understand the requirements for designing, permitting, installing, and interconnecting PV systems in utility-connected applications. The workshop is designed for designers, engineers, architects, inspectors, and PV installers, who wish to stay informed of the latest design and code compliance issues that facilitate safe and long-lasting PV systems. Participants will be provided with an overview of the codes and standards that govern small-scale solar electrical generation. Primary focus is on the National Electrical Code (NEC), with a permit and inspection guideline provided to organize the permitting process.

5. Rating PV Power and Energy: Cell, Module, and System Measurements:

Instructor - Dr. Keith Emery, National Renewable Energy LaboratorySynopsis - The tutorial will cover the state-of-the-art in theory, standards, procedures, and hardware used to determine the power and energy of PV cells, modules and systems. The measurement theory for evaluating the PV power for flat-plate or concentrating single- or multi-junction PV is discussed. Applicable ASTM, IEC and ISO standards are described along with a discussion on the plethora of sources of uncertainty in the measurements. Merits and limitations of the standards and current practices in predicting the PV delivered are described.

TU

TO

RIA

L P

RO

GR

AM

20


PM TUTORIALS (1:30 PM – 5:00 PM)

6. Thin Film Solar Cells

Instructor - Dr. Tim Gessert, National Renewable Energy LaboratorySynopsis - The tutorial will provide a background of the present state of thin-film photovoltaic (PV) solar cell technologies and markets within the context of expected national and global future energy requirements. The technologies discussed will be those in present world-wide production, focusing on amorphous Silicon (a-Si), Copper Indium Gallium Diselenide (CIGS), and Cadmium Telluride (CdTe). For each technology, discussion will include historical development, present advantages and limitation, and possible future directions for improved devices and modules. A very condensed discussion of PV device physics will be provided to establish an appreciation of material parameters that are important to related device operation. The tutorial will also discuss advancements in related technologies that may be critical for accelerating deployment of thin-film PV products. Examples of this include development of thin-film PV specific glass and device-specific transparent conducting oxides and buffer layers.

7. Organic Solar Cells: Principles and Cell Design

Instructor - Dr. Paul Berger, Professor at Ohio State UniversitySynopsis - This course will aim to bridge the knowledge and vocabulary gap between the inorganic and organic PV communities. No prior knowledge of organic chemistry is required. The current state of organic PV will be reviewed. Although organic solar cells have improved rapidly from very low efficiencies to moderate efficiencies of ~3−5%, the overall performance of organic solar cells is not yet high enough for commercial opportunities. Organic PV is stymied now at around 5-6% efficiency for conversion of sunlight to electricity [source: NREL]. A 10% efficiency is considered the commercial breakthrough point. The key advantages of organic photovoltaic (PV) technology will be discussed, including the inherent lower cost of organic PV vs. inorganic semiconductors; the typically very high optical absorption coefficients (>105 cm-1) of organic materials; the compatibility with plastic substrates; and the high-throughput low temperature processes for low-cost roll-to-roll high volume manufacturing.

TU

TO

RIA

L P

RO

GR

AM


21


8. Reliability: From PV Cell to Module to System

Instructor - Ian Aeby, Director of Quality and Reliability, Emcore PhotovoltaicsaSynopsis - As the size and complexity of PV projects grow, device, subcomponent, module, and overall system reliability has become one of the primary considerations for assessing their economic and technical viability. This tutorial will provide a historical perspective on PV reliability across a variety of technologies and application (cSi, Thin Film, Multi-junction, CPV, Space, Terrestrial, etc.) followed by in-depth discussions of device physics, known and theoretical failure mechanisms, failure analysis techniques (LIV, DIV, EL, EBIC, TIVA, STEM, etc.), lifetime measurement and prediction models and methods (HALT, HAST, TC, DH, CE, Arrhenius, Weibull, etc.), and industry standards for product qualification (UL, IEC, Mil STD, AIAA, etc.).

9. Novel PV Approaches

Instructor - Dr. Chris Honsburg, Professor at Arizona State UniversitySynopsis - The purpose of this class is to review the “Third Wave” of PV, novel approaches to lower cost power generation by PV devices. Included will be discussions of mid-band solar cells, hot carrier cells, up conversion, down conversion, etc.

10. Photovoltaics 201

Instructor - Dr. Steve Fonash, Professor at Penn State UniversitySynopsis - This tutorial is a more advanced class in the operating principles of solar cells. The focus of the tutorial will be on using a free share ware PV 1D modeling program developed by Dr. Fonash. Students will be required to provide a laptop, and a copy of Dr. Fonash’s textbook will be provided as part of the cost of this tutorial. Topics covered will be materials properties and device physics of solar cells, homojunction and heterojunction cells, surface barrier cells, and dye sensitized cells. There will be a higher cost for this tutorial due to the inclusion of the textbook in the tutorial materials.

TU

TO

RIA

L P

RO

GR

AM

22


SOCIAL PROGRAM

Aloha,

I am PJ Walters, and as Social Program Chair, I invite you to join in on the fun events planned for the Photovoltaics conference. One goal of this conference is to build relationships on a social as well as professional level enhancing our Photovoltaic Specialist Community. Throughout the week, there are social events related to the conference, also daily sightseeing tours and organized activities. Please join in all or as many events as you wish, creating memorable enjoyment among our community of Photovoltaic Specialists, families, and friends.

Details of our social events schedule are to follow. Bear in mind, I have negotiated the lowest group rates, and all the tours, events, and receptions are family friendly.

It has been a pleasure to assist the organization of the social itinerary. I look forward to meeting up with you for the 2010 conference, having a wonderful time spent on the historic and beautiful island of Oahu.

Mahalo nui loa!PJ Walters

SO

CIA

L P

RO

GR

AM


23


FESTIVITIES ROOM (AVAILABLE DAILY)

Because we are special, we have a dedicated space at the hotel to rendezvous, socialize, and be merry. This is Kahili 2 in the Kalia Tower. Start each morning here with a complimetary continental breakfast. Companions are encouraged to make full use of this room.

SATURDAY, JUNE 19TH

POLYNESIAN CULTURAL CENTERFrom @11am to @10:30pm

We are planning a full day to evening trip to the PCC scheduled on Saturday, June 19, 2010 before the conference officially begins. The PCC is an absolutely wonderful location that immerses you in the cultures from across the South Pacific including Tahiti, Tonga, Fiji, Samoa, New Zealand and Old Hawaii. The Center is staffed with natives from these places that are students at Brigham Young University on Oahu. The trip includes the IMAX film “The Coral Reef” telling the story of how reefs are formed, as well as steps being taken to preserve them and the “Rainbows of Paradise” pageant of long canoes. The evening culminates with a sumptuous luau dinner buffet. Remember to bring your camera!

Please meet in the Festivities Room (Kahili 2 in the Kalia Tower) at 11 AM and then we will move to the busses from there.

$165 per adult | $125 children 5-16 years old

SUNDAY, JUNE 20TH

WELCOME RECEPTION AT THE HILTONFrom 6pm-8pm

As part of our incentives to stay at the conference hotel, the Hilton Hawaiian Village, will host a reception Sunday evening for conference attendees, and their families & companions staying at the Hilton. The reception will be in the Paradise Lounge in the Rainbow Tower overlooking the Hilton Lagoon. Beer, wine, soft drinks and snacks will be served. Your conference name badge and your hotel room key will be your admittance to this event.

SO

CIA

L P

RO

GR

AM

24


MONDAY, JUNE 21

STARS AND STRIPES TOURFrom 8am-2pm

On Monday, we will spend our morning at Pearl Harbor learning the history of “…a date which will live in infamy...”Franklin D. Roosevelt. This is an essential

experience when visiting Oahu. We will be given exclusive guided tours of the USS Arizona Memorial and the Battleship Missouri. These historic vessels mark the beginning and end of WWII. On our return, we will enjoy a driving tour of Chinatown and stop at the renowned Indigo restaurant for Lunch. Indigo offers a delectable buffet lunch that is another must do in Oahu. Remember your camera.

Please meet in the Festivities Room (Kahili 2 in the Kalia Tower) at 7 AM. This will give us a chance to get a quick bite to eat and cup of coffee and then move to the busses.

$100 per adult$ 90 children 5-16 years old

EXHIBIT HALL OPENING RECEPTIONFrom 6pm-8pm

Monday evening, the Exhibitors will host a reception in the Exhibit Hall within the Convention Center to mark the opening of the Exhibits. Refreshing beverages and good food will be served. Join us in the Exhibit Hall to view the latest developments in the PV Industry and find the companies giving away the best swag.

SO

CIA

L P

RO

GR

AM


25


TUESDAY, JUNE 22

DOLE PLANTATION TOURFrom 9am-1pm

Do pineapples grow on trees? Join us on this half-day trip to find out. The Dole Plantation offers acres of pineapples, a garden maze, train tour, a restaurant and general store perfect for gathering all the souvenirs and goodies you will want to bring back to the mainland. Experience for yourself, how amazingly sweet the air smells at the pineapple plantation.

Please meet in the Festivities Room (Kahili 2 in the Kalia Tower) at 8:30 AM and we will move to the busses from there.

$57 per ticket

TUESDAY EVENING, JUNE 22

CHERRY AWARD RECEPTIONFrom 6pm-8pm

Each year, the conference hosts a reception to celebrate the Cherry Award winner. We will hold this reception on the Lagoon Lawn at the Hilton which is a gorgeous location with a great view of the sunset! Open bar and light fare will be served. Your conference badge will be your ticket to this event.

SO

CIA

L P

RO

GR

AM

26


WEDNESDAY, JUNE 23

GRAND ISLAND CIRCLE TOURFrom 9am-4pm

On Wednesday, we will embark on a full day trip around the island stopping at several places to provide an overall experience of Oahu. Going counterclockwise from the Hilton, we will visit the Pali Lookout, the Byodo Temple and then stop at Turtle Bay for lunch. After lunch, we will tour the North Shore including Sunset Beach, Waimea Falls Park, and Halewia town where we will visit the North Shore Surf Museum. Dress casual and wear comfortable shoes. There is a minimal paved walk to the waterfall. Remember to bring your camera and bottled water.

Please meet in the Festivities Room (Kahili 2 in the Kalia Tower) at 8:30 AM and we will move to the busses from there.

$120 per ticket

SUN RUN

The 2010 IEEE PVSC Sun Run will be held along the beautiful waterfront and beaches of Waikiki for this event, which is now 30 years old! The start and finish for this run will be right outside the Hilton Hawaiian Hotel. The run will be held on Wednesday morning, June 23. There will be no problems in getting back in time for the presenters’ breakfast and the sessions! Runners (both competitive and less so!) can register at the meeting-in the area of the conference registration itself. The registration fee will cover tasteful run T-shirts, refreshment, and recognitions for outstanding performances. As usual, awards will be made in several age categories for both men and women competitors. Again, we will have the Corporate Cup run for teams (3 or more runners) for which the times will be handicapped by both age and gender using the long-tested (since 1984!) Modified Arvizu-Kazmerski adjustment system.

SO

CIA

L P

RO

GR

AM


27


THURSDAY, JUNE 24

SURF LESSONSFrom 10am

What trip to Hawaii is complete without surfing? We will have an special group surf lesson for our conference. We will meet in the Companion Room Thursday morning at 10AM, and we will move as a group from there to the beach. You will pay for this at the time of the lesson, and we are presently negotiating the final price. Check back for more details. Please register now to indicate your intention to join us.

THURSDAY EVENING, JUNE 24

CONFERENCE BANQUET AT ‘IOLANI PALACEFrom 6:30pm-9:30pm

You do not want to miss this once in a lifetime conference banquet. The ‘Iolani Palace is simply beautiful, and is the only royal residence in the United States. The palace was home to the last monarchs of Hawaii from 1882- 1893. Tours of the palace will be given upon arrival. The Hawaiian Trio will provide entertainment for the evening. There will be open bar, and the food by Chef Glenn Chu, owner of the exciting

Indigo Restaurant is phenomenal. $60 per adult | $35 for students | $30 children

FRIDAY, JUNE 25

MORNING YOGA ON WAIKIKI

Imagine the peace and tranquility of sunrise on beautiful Waikiki Beach. A perfect setting for morning yoga. We have arranged for a group yoga session for our conference on Friday morning. This will be complimentary for our attendees. We are making final arrangements, so please check back for final details on time and location. Please register now to indicate your intention to join us. For details and information, you can contact the registration desk.

SO

CIA

L P

RO

GR

AM

28


ORGANIZING COMMITTEE

CONFERENCE GENERAL CHAIRRobert J. Walters Naval Research Laboratory

SECRETARY/ CHAIR-ELECTDavid M. Wilt Air Force Research Laboratory

PAST CHAIRTimothy J. Anderson University of Florida

TREASURERB.J. Stanbery HelioVolt Corporation

PROGRAM COMMITTEERichard R. King, Chair Spectrolab

Ryne Raffaelle National Renewable Energy Laboratory

Rommel Noufi National Renewable Energy Laboratory

Frank Dimroth Fraunhofer Institut fur Solare Energiesysteme

Klaus Weber The Australian National University

Arno Smets Eindhoven University of Technology

David Ginley National Renewable Energy Laboratory

Alex Howard Air Force Research Laboratory

Angus Rockett University of Illinois

Angele Reinders University of Twente

John Benner National Renewable Energy Laboratory

POSTERSMerhan Arbab PPG Industries, Inc.

CO

MM

ITTEES


29


TUTORIALSPaul Sharps Emcore Photovoltaics

OPERATIONSRyne Raffaelle National Renewable Energy Laboratory

REGISTRATIONWendy Larsen Bowen

DEPUTY REGISTRATIONAlex Howard Air Force Research Laboratory

PUBLICATIONS & PRESENTATIONSJennifer Granata Sandia National Laboratory

DEPUTY PUBLICATIONS & PRESENTATIONSSimon Liu Aerospace Organization

GRADUATE STUDENT COORDINATORSeth Hubbard Rochester Institute of Technology

LEAD GRADUATE STUDENT ASSISTANTJessica Adams Imperial College of London

PUBLICITYTheresa Jester Hudson Clean Energy Partners

DEPUTY PUBLICITYAngus Rockett University of Illinois

EXHIBITS John Martin Qioptiq Space Technology

DEPUTY EXHIBITSMichael Pieszcor National Aeronautics and Space Administration

WEB MASTERBrent Nelson National Renewable Energy Laboratory

AWARDSCory Cress Naval Research Laboratory

CO

MM

ITTEES

30


ORGANIZING COMMITTEE (continued)

INTERNATIONAL PROGRAMRichard M. Swanson, Chair SunPower Corporation

Francesca Ferrazza, Co-chair Eni S.p.A.

Masafumi Yamaguchi, Co-chair Toyota Technical Institute

SCHOOL PROGRAMMartha Symko-Davies National Renewable Energy Laboratory

DEPUTY SCHOOL PROGRAMKeith Emery National Renewable Energy Laboratory

SUN RUNLawrence L. Kazmerski National Renewable Energy Laboratory

SOCIAL PROGRAMPatricia Walters

IEEE/EDS REPRESENTATIVEJohn D. Meakin

ADMINISTRATIONAmerico F. Forestieri MOE Consulting

CO

MM

ITTEES


31


INTERNATIONAL COMMITTEE

Richard M. Swanson, Chair SunPower Corporation

Francesca Ferrazza, Co-chair Eni S.p.A.

Masafumi Yamaguchi, Co-chair Toyota Technical Institute

CO

MM

ITTEES

Tim AndersonUniversity of FloridaUSA

Sheila G. Bailey NASA Glenn Research CenterUSA

A. K. BaruaIndian Assoc. for Cultivation of ScienceINDIA

John BennerNational Renewable Energy LaboratoryUSA

Henry W. BrandhorstAuburn UniversityUSA

Tim BrutonNaRECUNITED KINGDOM

David E. CarlsonBP SolarUSA

Timothy J. CouttsNational Renewable Energy LaboratoryUSA

Antonia Sonia A. Cardoso Diniz CEMIG BRAZIL

Dennis J FloodNorth Coast Initiatives, Ltd. USA

Carlo FloresCESI S.p.AITALY

Takashi FuyukiNara Institute of Science and TechnologyJAPAN

Martin A. GreenUniversity of New South WalesAUSTRALIA

Huey-Liang HuangNational Tsing Hua UniversityTAIWAN, ROC

Lawrence L. KazmerskiNational Renewable Energy Lab.USA

Donghwan KimKorea UniversityKOREA

Richard J. KingU. S. Department of EnergyUSA

Makoto KonagaiTokyo Institute of TechnologyJAPAN

Michio KondoNIAISTJAPAN

32


CO

MM

ITTEES

Kosuke KurokawaTokyo A &T UniversityJAPAN

Antonio LuqueIES - UPMSPAIN

Heinz OssenbrinkEuropean Commission DG JRCITALY

S.PanyakeowChulalongkorn UniversityTHAILAND

Nicola PearsallUniversity of NorthumbriaUNITED KINGDOM

Josef PoortmansIMECBELGIUM

Ajeet RohatgiGeorgia Institute of TechnologyUSA

Richard J. Schwartz Purdue UniversityUSA

Wim SinkeECNTHE NETHERLANDS

Jinsoo SongKorea Institute of Energy ResearchKOREA

Tatsuya TakamotoSharp Corporation JAPAN

Marko TopicUniversity of LjubljanaSLOVENIA

Robert J. WaltersNaval Research LaboratoryUSA

Gerhard WiliekeFHG-ISEGERMANY

Christopher R. WronskiPennsylvania State UniversityUSA

Yuwen ZhaoBeijing Solar Energy Research InstituteCHINA

INTERNATIONAL COMMITTEE (continued)


33


CO

MM

ITTEESPROGRAM COMMITTEE

Richard R. King, ChairSpectrolab

Area 1: Fundamentals and New Concepts for Future Technologies

Chair: Ryne Raffaelle, National Center for Photovoltaics, Golden, Colorado, USACo-Chair: N. (Ned) Ekins-Daukes, Imperial College, London, United KingdomCo-Chair: Yoshitaka Okada, The University of Tokyo, Japan

Area 2: CIGS and CdTe Thin Film Solar Cells and Related Materials

Chair: Rommel Noufi, National Renewable Energy Laboratory, Golden, Colorado, USACo-Chair: Tokio Nakada, Aoyama Gakuin University, JapanCo-Chair: Hans-Werner Schock, Helmholtz-Zentrum Berlin, GermanyCo-Chair: Ayodhya N. Tiwari, EMPA, Swiss Federal Laboratory, SwitzerlandCo-Chair: Jim Sites, Colorado State University, USA

Area 3: III-V and Concentrator Technologies

Chair: Frank Dimroth, Fraunhofer ISE, Freiburg, GermanyCo-Chair: Sarah Kurtz, National Renewable Energy Laboratory, Golden, Colorado, USACo-Chair: Kenji Araki, Daido Steel, Japan

Area 4: Crystalline Silicon Technologies

Chair: Klaus Weber, Australian National Univ., Canberra, AustraliaCo-Chair: Stefan Glunz, Fraunhofer ISE, Freiburg. GermanyCo-Chair: Stuart Bowden, Arizona State University, USA

Area 5: Amorphous, Nano, and Film Si Technologies

Chair: Arno Smets, Eindhoven Univ. of Technology, The NetherlandsCo-Chair: Sumit Agarwal, Colorado School of Mines, USACo-Chair: Takuya Matsui, National Institute of Advanced Industrial Science and Technology, Japan

34


CO

MM

ITTEES

PROGRAM COMMITTEE (continued)

Area 6: Organic Photovoltaics

Chair: David Ginley, National Renewable Energy Laboratory, Golden, Colorado, USACo-Chair: Jan Kroon, ECN, The NetherlandsCo-Chair: Gitti Frey, Technion, Israel

Area 7: Space Technologies

Chair: Alex Howard, AFRL, Kirtland Air Force Base, Albuquerque, NMCo-Chair: Mitsuru Imaizumi, JAXA, JapanCo-Chair: Carsten Baur, ESA

Area 8: Advances in Characterization of Photovoltaics

Chair: Angus Rockett, Univ. of Illinois, Urbana- Champaign, USACo-Chair: Gerald Siefer, Fraunhofer ISE, Freiburg, GermanyCo-Chair: Manuel Romero, National Renewable Energy Laboratory, Golden, Colorado, USACo-Chair: Ayodhya Tiwari, EMPA, Swiss Federal Laboratory, SwitzerlandCo-Chair: Yoshihiro Hishikawa, Advanced Industrial Science and Technology (AIST), Tsukuba, JapanCo-Chair: Thorsten Trupke, BT Imaging Pty Ltd, Surry Hills, Australia

Area 9: PV Modules and Terrestrial Systems

Chair: Angèle Reinders, University of Twente, Enschede, The NetherlandsCo-Chair: Terry Jester, Hudson Clean Energy Partners, USACo-Chair: Pierre Verlinden, Solar Systems, Australia

Area 10: PV Velocity Forum: Accelerating the PV Economy

Chair: John Benner, National Renewable Energy Laboratory, Golden, ColoradoCo-Chair: B. J. Stanbery, HelioVolt Corp., Austin, Texas, USACo-Chair: Carol Tombari, NREL, Golden, Colorado, USACo-Chair: Elaine Ulrich, New West Technologies, USACo-Chair: Timothy Coutts, USA


35


CO

MM

ITTEESWILLIAM R. CHERRY COMMITTEE

Timothy Coutts, ChairNational Renewable Energy Laboratory

Antonio Luque, Awards ChairInstituto De Energia Solar - UPM

Timothy AndersonUniversity of Florida

Charles BackusASU Research Park

Sheila G. BaileyNASA Glenn Research Center

Allen M. BarnettUniversity of Delaware

Paul BasoreRenewable Energy Corp. ASA

John BennerNational Renewable Energy Laboratory

Henry W. Brandhorst, Jr.Auburn University

David E. CarlsonBP Solar

Dennis J. Flood North Coast Initiatives Ltd.

Americo F. ForestieriMOE Consulting

Martin A. GreenUniversity of New South Wales

Peter Iles

Lawrence L. KazmerskiNational Renewable Energy Laboratory

John D. MeakinUniversity of Maryland

Eugene RalphPV Consulting

Ajeet RohatgiGeorgia Institute of Technology

Richard J. SchwartzPurdue University

Richard M. SwansonSunPower Corporation

Stuart WenhamUniversity of New South Wales

Christopher R. WronskiPennsylvania State University

Masafumi YamaguchiToyota Technical Institute

36


EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP

EXHIBIT HALL MAP

MEDIA SPONSORS

302

304

309

326 327

328 329

408 411 510

515

POSTER SESSIONS

GES

CYBER CAFE

509

512413

412313

306

503

505

300

AISL

E

400

AISL

E

500

AISL

E

STAGE

DEMO PRODUCT AREA

312

314

303

305

402

404

502

504

403

318

320

322

A1 B1

A24 B24

A29 B29

A34 B34

C1 D1

C34 D34

E1 F1

E34 F34

G1 H1

G34 H34

I1 J1

I34 J34

K1 L1

K34 L34

M1 N1

M24 N24

M29 N29

M34 N34

O1 P1

O24 P24

O29 P29

O34 P34

Q1 R1

Q34 R34

S1 T1

S34 T34

U1 V1

U34 V34W34 X34

W1 X1

101PVSC High School Program

JDSU BergerLichttechnik

NavalResearchLaboratory

Alpha-OmegaPower Tech

LLC

Sinton Inst

PVMeasurements,

Inc

Newport Corp.

NationalRenewable

EnergyLaboratory

(NREL)

Keithley Inst

Spire Corp

OAI

EvansAnalytical

Group

EMCORE Corp

Abet Tech RASIRC

Veeco Inst Inc.

Ferro ElectMaterials

EpiWorks

Spectrolab, Inc. FreibergInst GmbH

Photon Europe& Photon

USA

Qioptiq Ltd.

Xtreme Power

J. A. WoollamCo., Inc

Entegris

Photo EmissionTech., Inc

ATK Space Sys

HORIBAScientific

Hawaii StateEnergy

WOMEN MEN CONCESSION

ENTRANCEHIGH SCHOOL PROGRAM


37


EXHIBITOR DIRECTORY

Abet Technologies 328168 Old Gate LaneMilford, CT 06460203-540-9990203-301-0059asmith@abet-technologies.comwww.abet-technologies.comAbet Technologies manufacturers a broad range of standard and custom PV-IV test systems for solar cells up 210 x 210 mm, ASTM and IEC compliant steady state solar simulators, test stations from simple manual load to temperature stabilized vacuum chuck models, standards compliant software, calibrated reference cells, and a range of electronic loads for low and high current cells. Complete solutions are assembled and tested for performance before shipment or any one or all of the system components can be purchase separately.

Alpha-Omega Power Technologies, LLC 3058504 Calle Alameda NEAlbuquerque, NM 87113505-341-4828505-341-4829wrcravey@aol.comwww.alphaomegapt.comAlpha-Omega Power Technologies (AOPT) has developed a line of pulsed concentrator photovoltaic (CPV) solar simulators based on its patented high speed, high power load. If you are looking for a 1 sun, large area pulsed solar simulator (LAPSS) system or a high intensity pulsed solar simulator (HIPSS) system, AOPT has what you want. Check out our CPV and large area testers.

ATK Space Systems 512600 Pine StGoleta, CA [email protected] Space Systems, Goleta, previously AEC-Able, has been developing space solar arrays and deployable systems for over 30 years with 100% flight success. We are the leading independent solar array provider and have developed and produced numerous solar array systems for military (GPS IIF satellites), civil (Deep Space 1, Mars Phoenix Lander, AIM, STP-SIV, Orbital Express), and commercial (Orbital’s STAR2 GEO Satellites) markets. Currently we are developing the 7.5kW UltraFlex solar array wings for CEV Orion and the solar array deployable structure for NPOESS.

EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP

38


Berger Lichttechnik 303150 Wolfratshauser Strasse82049 PullachGermany490-89-793-55-266maurice@bergerlichttechnik.dewww.bergerlichttechnik.de

Dark Field Technologies, Inc. 21870 Robinson BlvdOrange, CT 06477203-298-0731203-298-0732jepotts@darkfield.comwww.darkfield.comDark Field Technologies designs and builds high-resolution laser and camera systems for 100% on-line,real-time thin film PV defect detection and metrology. Dark Field is the only company delivering 100% scribe metrology, on-line,real-time(widths, offsets, pitch ±2µm)regardless of scribe orientation. Advanced, proprietary systems operate in thin film PV,CPV,CSP, glass,metal coil & film production. New scanner technology delivers 100% haze measurement,mapping and alarms on-line. NxtGenTM systems measure glass warp and wedge as well as panel length, width and squareness.

EMCORE Corporation 32710420 Research Rd, SEBldg 1Albuquerque, NM 87123505-332-5000505-332-5100mary_beth_chumney@emcore.comwww.emcore.comEMCORE is a leading manufacturer of high-efficiency triple-junction solar cells, covered-interconnected-cells (CICs) and solar panels for the space industry. EMCORE also provides concentrator photovoltaic (CPV) systems for utility-scale solar applications as well as components and modules for use in CPV systems.

EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP


39


Entegris 509101 Peavey RdChaska, MN 55318952-556-3131952-556-1880ann_knutson@entegris.comwww.entegris.comFor more than 40 years, Entegris has provided products, materials and systems that purify, protect and transport the critical materials that enable the world’s leading technologies. Our expertise in wet chemistries, gas processes and materials science is built from a product offering of gas/liquid filters and purifiers; fluid handling components; wafer and substrate carriers; specialty coatings, graphite and silicon carbide; sensing and control devices; and chemical blending solutions.

EpiWorks 4041606 Rion DriveChampaign, IL 61822217-373-1590217-373-1591sales@epiworks.comwww.epiworks.comEpiWorks is a leader in the manufacture and development of III-V epitaxial wafers for solar cells, lasers, photodetectors and RF devices. EpiWorks’ products include III-V based photovoltaic wafers, such as high-efficiency dual and triple-junction structures on III-V and Ge-based substrates. In addition to high-quality manufacturing, our business model includes high-level customer interaction and custom technology development.

Evans Analytical Group 322810 Kifer RdSunnyvale, CA 94086408-530-3500408-530-3501cgentile@eaglabs.comwww.eaglabs.comEvans Analytical Group (EAG) is the leading provider of surface analysis and materials characterization services to the photovoltaic industry. We provide high quality analytical services with fast turnaround, helping customers with R&D and also troubleshooting. We have labs located around the world providing services such as SIMS, GDMS and TEM.

EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP

40


Ferro Electronic Materials 4037500 E Pleasant Valley RdIndependence, OH 44131216-875-6100216-875-7255beercheckr@ferro.comwww.ferro.comFerro helps reduce silicon costs, deposition weight, and breakage while increasing performance and throughput. Products include front and back surface metallization materials, screen-printable diffusion solutions and aluminum BSF paste. These products offer the advantages of Ferro’s patented Hot Melt ink technology. This specially designed silver conductor system eliminates the drying process, resulting in higher throughput, increased productivity, improved yields, and reduced VOCs. Front silver contacts for shallow emitters improve power output.

Freiberg Instruments GmbH 411Am St Niclas Schacht 1309599 FreibergGermany49-3731-41954-1049-3731-41954-14dornich@freiberginstruments.comwww.freiberginstruments.comEquipment producer for contactless, destruction free inline characterisation of wafers, bricks and cell processes. Measuring minority carrier lifetime and photoconductivity with a so far not seen speed and sensitivity. Resistivity measurement options are available as well.

HORIBA Scientific 5153880 Park AveEdison, NJ 08820732-494-8660732-549-5125diane.surine@horiba.comwww.horiba.com/scientificHORIBA Scientific is displaying its line of complete solutions for PV development and manufacturing, including quantum yield via Photoluminescence (PL) and lifetimes, surface, films and depth analysis via GD-OES and ellipsometry, and stoichiometry and crystallinity via Raman. Also our comprehensive range of fluid control and analyzers, including the industry standard mass flow controllers.

EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP


41


J.A. Woollam Co., Inc. 410645 M StreetSuite 102Lincoln, NE 68508402-477-7501402-477-8214sales@jawoollam.comwww.jawoollam.comJ.A. Woollam Company offers a wide range of spectroscopic ellipsometers for nondestructive materials characterization, including thin film thickness (single and multilayer), optical constants, composition, growth/etch rates, and more. Instruments available for research and manufacturing metrology covering spectral ranges from vacuum ultra-violet to far infrared. Offering table-top, in-line, and in-situ models.

JDSU 302430 N McCarthy BlvdMilpitas, CA 95035408-546-5000408-546-4300nancy.perkins@jdsu.comwww.jdsu.comJDSU designs and manufactures concentrated photovoltaic cells in addition to solar-cell coverglass and optical solar reflectors for solar-energy and satellite-power applications. JDSU innovative design and high-repeatability and process-controlled manufacturing capabilities ensure high-quality, high-volume production for emerging and heritage market applications.

Keithley Instruments 31428775 Aurora RdSolon, OH 44139440-248-0400888-534-8453440-542-8017info@keithley.comwww.keithley.comWith more than 60 years of measurement expertise, Keithley Instruments is a world leader in advanced electrical test instruments and systems. Our customers are scientists and engineers in the worldwide electronics industry involved with advanced materials research, semiconductor device development and fabrication, and the production of end products such as portable wireless devices. The value we provide them is a combination of products for their critical measurement needs and a rich understanding of their applications.

EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP

42


National Renewable Energy Laboratory (NREL) 227National Center for Photovoltaics (NCPV)1617 Cole Blvd - MS 3221Golden, CO [email protected]/pvThe National Center for Photovoltaics (NCPV) within the National Renewable Energy Laboratory performs research on wide range of PV materials including c-Si, thin-film silicon, CIGS, CdTe, III-V-based high efficiency devices, and organic PV. The NCPV provides standard performance measurements of PV cells and modules, as well as reliability testing. The Process Development and Integration Laboratory is a unique facility where collaborators can work closely with NREL scientists. Stop by the booth for a schedule of times to visit and "meet the PV experts."

Naval Research Laboratory 2034555 Overlook Ave SWWashington, DC 20375202-767-3200202-404-3200julia.wyant@nrl.navy.milwww.nrl.navy.milThe Naval Research Laboratory (NRL) operates as the Navy's full-spectrum corporate laboratory, conducting a broadly based multidisciplinary program of scientific research and advanced technological development directed toward maritime applications of new and improved materials, techniques, equipment, systems and ocean, atmospheric, space sciences and related technologies. The Laboratory, with a total complement of nearly 2,500 personnel, is located in southwest Washington, DC, with other major sites at the Stennis Space Center, MS; and Monterey, CA.

Newport Corporation 3121791 Deere AveIrvine, CA 92606949-863-3144949-253-1680sales@newport.comwww.newport.comOriel® Instruments, a brand of Newport Corporation, has developed recognition in the optical research field as a reliable source for well engineered, durable Light Sources and their dedicated Power Supplies, as well as Light Detection Systems and Spectroscopy Instrumentation. Oriel also manufactures dedicated broadband light sources, monochromatic light sources and detectors for light measurement & characterization in sophisticated dedicated instrumentation.

EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP


43


Photo Emission Tech., Inc. 510760 Calle PlanoCamarillo, CA 93012805-482-5200805-482-5252mchawla@photoemission.comwww.photoemission.comWe manufacture & Market Cell Testers (Integrated Turn-Key Solar Cell Testing Systems) & Steady State Solar Simulators - Illumination area: 50mm x 50mm to 400mm x 400mm; Meets Class A ASTM E927, JIS C 8912-1989 and IEC 904 standards; AM1.5G; other filters optional I-V Measurement Systems - Current Range from 1A to up to 20A, Optional temperature control, 0o C to 60o C (wider ranges available) Spectral Response & QE Systems- EQE/IPCE, %; Optional IQE; Flexible configuration Spectro-Radiometers - 300-2,200nm Range

Photon Europe & Photon USA 412514 Bryant StSan Francisco, CA [email protected]

PV Measurements, Inc. 3095757 Central Ave.Suite BBoulder, CO [email protected] manufacturer of solar cell characterization equipment, including I-V testers, reference solar cells and QE measurement systems.

Qioptiq Space Technology 4132207 Avenida San AnteroCamarillo, CA 93010805-484-6061805-926-4050johnmartin@qioptiq-space.comwww.qioptiq.comQioptiq Space Technology is the world leader in the design and manufacture of specialized optical space components. QST provides ultra-thin, radiation stable glasses with thin film coatings for two main applications: “Optical Solar Reflectors” and “Solar Cell Coverglasses” specifically for space satellites. Current glass types include, CMX, CMG and CMO.

EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP

44


RASIRC 22811760 Sorrento Valley Rd - Ste ESan Diego, CA [email protected] products purify & deliver steam & water vapor in flow rates from ppm levels to liters per minute for a wide range of industries and applications. Only RASIRC humidifiers & steamers generate ultra high purity steam from DI water, reducing cost, increasing yield & improving safety for sputtering, diffusion & annealing of thin films, TCO layers & thermal oxides. Solar benefits are faster growth rates, lower cost substrates, lower process temperatures, reduced costs & higher efficiencies in ITO and other thin films. Custom systems are available upon request.

Sinton Instruments 3064720 Walnut St - Ste 102Boulder, CO 80301303-945-2113303-945-2199quotes@sintoninstruments.comwww.sintoninstruments.comSinton Instruments is the leading PV industry supplier of silicon test and measurement equipment. Our goal is to develop solutions to practical problems in R&D and manufacturing process control with physically rigorous analysis and cost-effective measurement tools. Winner of the R&D 100 award.

SPECTROLAB, INC. 40812500 Gladstone AveSylmar, CA 91342-5373818-365-4611818-361-5102silvestra.alexander@boeing.comwww.spectrolab.comSpectrolab, a whollly owned subsidiary of The Boeing Company, is the world's leading manufacturer of high-efficiency multijunction space and terrestrial solar cells, as well as, panels for space application. Spectrolab's product portfolio includes the world's most efficient space and terrestrial concentrator solar cells, photo-detectors, solar simulators and advanced searchlights.

EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP


45


Spire Corporation 318One Patriots ParkBedford, MA 01730781-275-6000781-275-7470apaglierani@spirecorp.comwww.spirecorp.comSpire Corporation is a leading global solar company providing turnkey solar factories, capital equipment, installed PV systems, and critical services worldwide. With over 40 years of experience and $100 million in R+D and PV, our unique experience and technical depth puts us in a unique position to ensure the success of our customers.

Veeco Instruments Inc. 402Terminal DrivePlainview, NY [email protected] over 40 years experience in vacuum deposition technology—unmatched by any other tool provider in the industry—Veeco is prepared to leverage our unique advantages to shape the future of thin film solar energy. Only Veeco can enable large volume CIGS thin film module production now. We are fully prepared to help thin film CIGS manufacturers implement the cost-effective, high-yield production platforms that will fuel the global success of solar power.

Xtreme Power 5021120 Goforth RdKyle, TX 78640512-268-8191888-263-5870jgelgand@xtremepowersolutions.comwww.xtremepower.comThe Xtreme Power Dynamic Power Resource, an intelligent energy storage and power management system, acts as a buffer between sensitive grids and clean, but intermittent solar power. Xtreme Power smooths renewable power and controls ramp excursions, improves ROI for Independent Power Producers by eliminating the need for curtailment, and reduces greenhouse gas emissions by significantly decreasing the need for spinning reserves and peaking power units.

EX

HIB

ITIO

N &

SP

ON

SO

RS

HIP

46


SU

ND

AY

TU

TO

RIA

LS

SUNDAY MORNING TUTORIALS8:30 am - 12:00 pm

Tutorial 1: Photovoltaics 101Lana’i 314

Dr. Fred NewmanStaff Scientist at Emcore Photovoltaics and Adjunct Professor at University of New Mexico

Tutorial 2: Silicon Solar Cell TechnologyKaua’i 311

Dr. Ron SintonSinton Instruments

Tutorial 3: High Efficiency Multi-junction Cell TechnologyMoloka’i 315

Dr. Frank DimrothFraunhofer Institute for Solar Energy

Tutorial 4: PV System Installation, Grid Integration, Permitting, etc.Maui 316C

Bill Brooks PEBrooks Engineering LLC

Tutorial 5: Rating PV Power and Energy: Cell, Module, and System MeasurementsNi’ihau 312

Dr. Keith EmeryNational Renewable Energy Laboratory

All tutorials are 3 hours long with a break from 10:00 AM - 10:30 AM.

Lunch break (on your own) between morning and afternoon tutorials from

12:00 PM - 1:30 PM.


47


SU

ND

AY

TU

TO

RIA

LSSUNDAY AFTERNOON TUTORIALS

1:30 pm - 5:00 pm

Tutorial 6: Thin Film Solar CellsKaua’i 311

Dr. Tim GessertNational Renewable Energy Laboratory

Tutorial 7: Organic Solar Cells: Principles and Cell DesignMaui 316C

Dr. Paul BergerProfessor at Ohio State University

Tutorial 8: Reliability: From PV Cell to Module to SystemNi’ihau 312

Ian AebyDirector of Quality and Reliability, Emcore Photovoltaics

Tutorial 9: Novel PV ApproachesLana’i 314

Dr. Chris Honsburg Professor at Arizona State University

Tutorial 10: Photovoltaics 201Moloka’i 315

Dr. Steve FonashProfessor at Penn State University

All tutorials are 3 hours long with a break from 3:00 PM - 3:30 PM.

Lunch break (on your own) between morning and afternoon tutorials from

12:00 PM - 1:30 PM.

48


INSTRUCTIONS TO ORAL PRESENTERS

Thank you for participating in the 35th IEEE PVSC as an oral presenter! As an Oral Presenter, the following lists your responsibilities:

• Be sure to upload your manuscript, following the guidelines on the PVSC website (http://www.ieee-pvsc.org/PVSC35/author-central.html), by June 20, 2010• Electronically sign the Copyright form and BRING A COPY WITH YOU• Upload your presentation at least 24 hours prior to your presentation following the guidelines on the A/V company’s website (see below). Bring your presentation on CD-ROM, Compact flash card, Memory Stick, Multi-media card, SD Card, or a laptop for transfer.• Even if you upload your presentation prior to the conference, be sure to check that it uploaded correctly by reviewing it in the Speaker Ready Room at the conference. Bring your presentation on CD-ROM, Compact flash card, Memory Stick, Multi-media card, SD Card, or a laptop as a backup.• Attend the Author’s Breakfast on the morning of (each of) your presentation(s) for instructions, to meet your session chair, and to be sure all your materials have uploaded correctly. Author’s Breakfast will be in Room 323 (Monday,Thursday, Friday) & Ballroom C (Tuesday, Wednesday).• Please arrive at your session 15 minutes before the scheduled start to coordinate with the session chairs, check that their presentation will display properly, and become familiar with the audio-visual equipment.

REMEMBER: No Paper, No Podium

If your manuscript has not been uploaded, you will not be allowed to present. If you (or a co-author) do not give your presentation, the manuscript will not be included in the proceedings.

Be sure to check the online program to confirm your presentation time and length!

INS

TR

UC

TIO

NS

TO

OR

AL P

RES

EN

TER

S


49


INS

TR

UC

TIO

NS

TO

OR

AL P

RES

EN

TER

SGuidelines for Computer Generated Presentations

Each speaker can bring their presentation to the Speaker Ready Room on CD-ROM, Compact flash card, Memory Stick, Multi-media card, SD Card, or a laptop 24 hours prior to the scheduled time of their presentation. Also, speakers can submit their presentation via the PGR Upload Center web site, http://www.davisdatacenter.com prior to the meeting.

Checking in to the Speaker Ready Room is the single most important action you will take to ensure your presentation is a success. All speakers are required to check into the Speaker Ready Room at least 24 hours before their presentation. The Speaker Ready Room will be open daily during the meeting.

When reviewing your presentation, you should make sure all fonts appear as expected and all sound/video clips are working properly. You will be able to edit your presentation at this time. The file will then be transferred to the computer network at the meeting. When the presentation is to be given, the file will be accessed via the conference menu on the computer in the meeting room. Once the presentation is launched, you (the speaker) will control the program from the podium using a computer mouse. At the end of the meeting, all files will be destroyed, and the computer hard drives will be reformatted.

We recommend PowerPoint for all users. A web browser with typical plug-ins will also be available (Internet Explorer). If you plan to use something besides Flash, Shockwave or Windows Media Player, and for a comprehensive overview of our guidelines, please check with our Presentation Guidelines: http://www.davisav.com/files/presentationguide.pdf to be sure your presentation will work properly.

The computers in the presentation rooms will be Windows-based PCs with Microsoft Power Point 2007 installed. All videos should be an .avi or .mpg (not .mov) format, so they will run properly on the computers provided. Presentations should be reviewed to be certain the fonts are displayed correctly.

For additional information on creating Power Point 2007 presentations or earlier versions, please see the Power Point Help website at http://office.microsoft.com/en-us/powerpoint/CH102247801033.aspx.

50


Media Supported

We recommend you bring at least 2 copies of your presentation to the meeting in case there is a problem with one of them. CD-R, CD-RW, Compact flash card, Memory Stick, Multi-media card or SD Card will be supported.

Ability to Edit PowerPoint Files in Speaker Ready Room

All PowerPoint presentations can be reviewed and edited in the Speaker Ready Room. It is recommended that all presentations be reviewed and edited for final version no less than two hours prior to the beginning of the session in which you are presenting.

Security

· Floppy drives and USB ports on the computers are disabled so no presentations can be copied.

· Cameras and video equipment are not permitted in the Speaker Ready Room.

· All files on the computers are deleted at the end of the conference.

Fonts: We can only supply fonts that are included in the base installation of Windows. Any font other than these will need to be embedded into your PowerPoint presentation. For information on embedding fonts see below. We suggest using the fonts such as Times New Roman, Arial and Tahoma. Use of fonts not included in Windows can lead to words that bleed into graphics or bullets that may be the wrong style.

INS

TR

UC

TIO

NS

TO

OR

AL P

RES

EN

TER

S


51


INSTRUCTIONS TO POSTER PRESENTERS

Congratulations on being chosen to present a poster at the 35th PVSC! Poster sessions are critical to the success of the conference, contributing to both the breadth and the depth of coverage in photovoltaic technology. Poster papers make it possible for a large number of important developments in the field of photovoltaics to be presented. In addition, the poster sessions allow authors the opportunity to personally interact and network with interested parties, and discuss research results at a level of detail that cannot be approached in formal questions following an oral presentation.

Please be sure to attend the Author’s Breakfast on the morning of (each of) your presentation(s) for instructions, to meet your session chair, and to be sure all your materials have uploaded correctly. Author’s Breakfast will be in Room 323 (Monday,Thursday, Friday) & Ballroom C (Tuesday, Wednesday).

The posters will all be displayed in the KAMEHAMEHA EXHIBIT HALL III. All posters will be displayed from Monday through Thursday. Poster boards will be arranged with letters designating each aisle and numbered poster position on each aisle. Specific locations for your poster will be available on this website in June.

Poster SizeThe area available for the poster is limited to a rectangle 48 inch tall by 36 inch wide (122 cm by 91 cm). THE POSTER CHAIR RESERVES THE RIGHT TO TRIM ANY POSTERS LARGER THAN THE ALLOCATED SIZE TO THE ALLOCATED SIZE!!! Tables in front of poster boards are PROHIBITED.

FormatPoster materials must be legible from a distance of two meters. Lettering in text and figures should be at least 5 mm, and the headings should be at least 10 mm. The title of the paper, the authors, and their affiliations should appear near the top of the poster in letters approximately 25 mm high.

MountingThe surface of the mounting board is pushpin friendly. Posters must be mounted to the boards with pushpins. Push pins will NOT be available at the conference; you must bring your own. We also recommend that you attach an envelope near the bottom of the poster for people to leave business cards for reprints, etc. Please do not leave reprints of the paper on the floor.

INS

TR

UC

TIO

NS

TO

PO

STER

PR

ES

EN

TER

S

52


The poster boards will be available on the morning of Monday June 21 for mounting your poster. You must mount your posters between 8:00 AM to 1:00 PM. Posters will need to be down by 2:00 PM Thursday June 24. Any posters not removed on time will be removed and discarded.

Manuscript1. Be sure to upload your manuscript, following the guidelines on the PVSC website (http://www.ieee-pvsc.org/PVSC35/author-central.html), by June 20, 20102. Electronically sign the Copyright form and BRING A COPY WITH YOU3. Manuscripts are required for all oral and poster presentations in Areas 1-9. Manuscripts are accepted for oral and poster presentations in Area 10, but are not required. Please follow the guidelines provided in Author Central Step 4 (http://www.ieee-pvsc.org/PVSC35/author-central.html). We value ALL your contributions and expect each to be represented in the Proceedings.

Remember: If you have not uploaded your paper, you will not be allowed to present!

Best Poster AwardTo encourage excellence in poster paper content and presentation, a Poster Award Program is sponsored by the conference committee. Poster judges will review posters and select one for an award from each of the seven technical areas in the program. The judging criteria will be based on technical content, clarity of presentation and the significance of the work. The primary author of each award winning paper will receive a certificate at the closing ceremony on Friday, June 25th. A personalized plaque will be mailed to the primary author of award winning posters during the month following the conference.

INS

TR

UC

TIO

NS

TO

PO

STER

PR

ES

EN

TER

S


53


TECHNICAL PROGRAM

As Program Chair, I am very pleased to welcome you to Honolulu for the 35th IEEE PVSC! On the following pages you will find the Technical Program for the conference, covering the latest breakthroughs and developments in practically every branch of photovoltaics research and technology. Enthusiasm to share the latest findings in our field of photovoltaics was overwhelming this year – over 1000 abstracts were submitted by solar cell researchers, more than ever before at the PVSC, and roughly 50% more than in the previous year. Thank you to all authors and attendees of the conference for your commitment to advancing the science and technology of photovoltaics.

We are in the midst of a crucial time for energy management on our planet. Environmental, climate change, and energy security concerns are among the most pressing issues we face today. Clearly, photovoltaics can be part of the solution. Public awareness is growing that photovoltaics can shape energy use patterns for future generations – much as the automobile transformed transportation within a time span of 50 years – as evidenced by the exponential rise in photovoltaic production over the last decade. Science and technology developments in PV over the next several years, and their influence on the economics of PV installations, are likely to establish which energy technologies become dominant for decades to come. The chance to share and discuss these crucial PV developments in a timely and influential forum is what the PVSC is all about.

The technical sessions are organized into 10 major areas:

Area 1: Fundamentals and New Concepts for Future Technologies Chair: Ryne Raffaelle, National Center for Photovoltaics, Golden, Colorado, USA

Area 2: CIGS and CdTe Thin Film Solar Cells and Related Materials Chair: Rommel Noufi, National Renewable Energy Laboratory, Golden, Colorado, USA

TEC

HN

ICA

L P

RO

GR

AM

54


Area 3: III-V and Concentrator Technologies Chair: Frank Dimroth, Fraunhofer ISE, Freiburg, Germany

Area 4: Crystalline Silicon Technologies Chair: Klaus Weber, Australian National Univ., Canberra, Australia

Area 5: Amorphous, Nano, and Film Si Technologies Chair: Arno Smets, Eindhoven Univ. of Technology, The Netherlands

Area 6: Organic Photovoltaics Chair: David Ginley, National Renewable Energy Laboratory, Golden, Colorado, USA

Area 7: Space Technologies Chair: Alex Howard, AFRL, Kirtland Air Force Base, Albuquerque, NM

Area 8: Advances in Characterization of Photovoltaics Chair: Angus Rockett, Univ. of Illinois, Urbana- Champaign, USA

Area 9: PV Modules and Terrestrial Systems Chair: Angèle Reinders, University of Twente, Enschede, The Netherlands

Area 10: PV Velocity Forum: Accelerating the PV Economy Chair: John Benner, National Renewable Energy Laboratory, Golden, Colorado

In addition to the Area Chairs above, we have adopted a system of international Co-Chairs for each technical area, covering the home regions of the three major photovoltaics conferences across the globe, to further foster international participation and collaboration at the PVSC. Over half of submitted abstracts came from outside North America, with Japan, Germany, South Korea, and Taiwan having particularly strong showings.

We have started two new technical areas at the 35th PVSC. In recognition of the rapidly growing interest in organic photovoltaics and dye-sensitized solar cells, which had previously been part of Area 1, we have launched Area 6: Organic Photovoltaics. The other new area is Area 8: Advances in Characterization of Photovoltaics. Here the focus is on methods of measurement and analysis themselves, rather than on a particular photovoltaic material system. By breaking these topics out separately in Area 8, it is hoped that

TEC

HN

ICA

L P

RO

GR

AM


55


researchers will have more exposure to characterization tools typically used for PV materials outside their area of specialization. This cross-fertilization will hopefully give researchers some 'new eyes' with which to look at their PV materials.

On Sunday, June 20, 2010, the first day of the conference, we continue PVSC tradition by beginning with a series of highly informative tutorials, taught by some of the top experts in their fields, on a wide range of PV topics. Those just coming into the field of photovoltaics as well as seasoned PV researchers can benefit from these excellent seminars.

Monday morning will feature our Keynote and Conference Plenary speakers, with talks of high interest and relevance to all at the conference, cutting across all technical areas. On Monday, Tuesday, and Wednesday mornings starting at 8:30 AM, we will have the Area Plenary talks in technical Areas 1-9. These talks will highlight particularly exciting results in each Area, and should be very interesting to anyone curious about PV fields outside their immediate area of expertise. Over 250 oral presentations are scheduled Monday through Friday noon, organized into sessions in 6 parallel time slots running throughout most of the week. Many of the parallel oral sessions throughout the week will begin with 30 min. extended talks, allowing some of the most notable scientific and technical advances at the meeting to be shared in greater depth, and helping to set the theme of the session. Again, these talks are a good opportunity for researchers interested in learning more about areas of PV outside their own.

Poster presentations will be an even more important part of the PVSC-35 than they have been in past conferences. With over 650 posters accepted for presentation at the conference, the impromptu discussions and meaningful dialogue fostered by the poster format will be the dominant forum for scientific exchange at the conference. During poster sessions there will be no oral sessions taking place at the same time, to allow uninterrupted time for discussion with the poster presenters. The poster sessions will take place in the Kamehameha Exhibit Hall III, and posters can be viewed from Monday noon through Thursday noon.

Motivated by the rapid commercialization of PV technology, the PV Velocity Forum, Area 10, is a parallel program that takes place throughout the week. The Forum will provide a unique opportunity for regulators, policy makers, legislators, investors and

TEC

HN

ICA

L P

RO

GR

AM

56


PV-industry executives to interact with scientists and technologists, to tackle the issues associated with the surging photovoltaics industry. Invited speakers and panelists will explore gating factors for incorporating new PV technologies, with the goal of accelerating the adoption of photovoltaics to a level even greater than we have today.

A small number of select papers from the IEEE PVSC are planned to be included in a special journal issue devoted to photovoltaics. All papers in the PVSC proceedings are searchable and accessible via the internet through the IEEE Xplore® system. To ensure IEEE Xplore®-compliant proceedings, please submit your manuscripts electronically through the website.

Thank you for joining us in Honolulu to make the 35th PVSC the place to be for solar cell researchers, technologists, entrepreneurs and policy makers, to present and learn about the latest advances in the science, engineering and applications of photovoltaics!

Richard R. KingProgram Chair, 35th PVSC

TEC

HN

ICA

L P

RO

GR

AM


57


AR

EA

1 P

RO

GR

AM

SU

MM

AR

YAREA 1 PROGRAM SUMMARY

Monday, June 21Plenary, Fundamentals & New Concepts 8:30 - 9:00 AM (Ballroom A/B) Orals, Fundamentals & New Concepts: Fundamental Mechanisms 2:00 - 3:30 PM (Ni’ihau 312) Tuesday, June 22Orals, Fundamentals & New Concepts: Multiple Quantum Well or Dot Solar Cells 1:30 - 3:00 PM (Ni’ihau 312) Posters, Fundamentals & New Concepts: Nanostructures 3:30 - 5:00 PM (Kamehameha Exhibit Hall III.a) Wednesday, June 23Orals, Fundamentals & New Concepts: New PV Materials II 1:30 - 3:00 PM (Ni’ihau 312) Posters, Fundamentals & New Concepts: Novel Mechanisms and Materials 3:30 - 5:00 PM (Kamehameha Exhibit Hall III.a) Late Night: Fundamentals & New Concepts: The Future of PV 7:00 - 9:00 PM (Hilton Rainbow Room) Thursday, June 24Posters, Fundamentals & New Concepts 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.a) Orals, Fundamentals & New Concepts: Nanowire Solar Cells 3:30 - 5:00 PM (Ni’ihau 312) Friday, June 25Orals, Fundamentals & New Concepts: New PV Materials I 8:30 - 10:00 AM (Ni’ihau 312) Orals, Fundamentals & New Concepts: Quantum Dot Solar Cells 10:30 - 12:00 PM (Ni’ihau 312)

58


AR

EA

2 P

RO

GR

AM

SU

MM

AR

Y

AREA 2 PROGRAM SUMMARY

Monday, June 21Plenary, CIGS & CdTe 9:00 - 9:30 AM (Ballroom A/B) Orals, CIGS & CdTe: Deposition & Characterization/Wide Band Gap & Novel Materials-I 2:00 - 3:30 PM (Kaua’i 311) Orals, CIGS & CdTe: Modules, Manufacturing, and Reliability 4:00 - 5:30 PM (Kaua’i 311) Tuesday, June 22Orals, CIGS & CdTe: Device Properties and Modeling/Characterization 1:30 - 3:00 PM (Kaua’i 311) Posters, CIGS & CdTe: CdTe and Other Materials 3:30 - 5:00 PM (Kamehameha Exhibit Hall III.b) Wednesday, June 23Posters, CIGS & CdTe: CIGS I and TCOs 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.a) Panel Discussion, PV Velocity Forum: Supply and Economics in Thin-Film PV Materials 1:30 - 5:00 PM (Maui 316C) Thursday, June 24Orals, CIGS & CdTe: Deposition & Characterization/Wide Band Gap & Novel Materials-II 8:30 - 10:00 AM (Kaua’i 311) Posters, CIGS & CdTe: CIGS II 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.b) Orals, CIGS & CdTe: Advanced Processes: Atmospheric and Vacuum 1:30 - 3:00 PM (Kaua’i 311) Orals, CIGS & CdTe: Deposition & Characterization/Wide Band Gap & Novel Materials-III 3:30 - 5:00 PM (Kaua’i 311) Friday, June 25Orals, CIGS & CdTe: Transparent Conductors, Buffers, and Contacts 8:30 - 10:00 AM (Kaua’i 311) Orals, CIGS & CdTe: Device and Module Reliability 10:30 - 12:00 PM (Kaua’i 311)


59


AR

EA

3 P

RO

GR

AM

SU

MM

AR

YAREA 3 PROGRAM SUMMARY

Monday, June 21Plenary, III-V’s & Concentrators 9:30 - 10:00 AM (Ballroom A/B) Orals, III-V’s & Concentrators: III-V Concentrator Solar Cells and Receivers 4:00 - 5:30 PM (Moloka’i 315) Tuesday, June 22Posters, III-V’s & Concentrators: III-V Concentrator Cells 3:30 - 5:00 PM (Kamehameha Exhibit Hall III.c) Wednesday, June 23Orals, III-V’s & Concentrators: Concentrator Modules and System Components 1:30 - 3:00 PM (Moloka’i 315) Posters, III-V’s & Concentrators: Concentrator Systems 3:30 - 5:00 PM (Kamehameha Exhibit Hall III.b) Thursday, June 24Orals, III-V’s & Concentrators: High and Low Concentration PV Systems and Plants 1:30 - 3:00 PM (Moloka’i 315) Friday, June 25Orals, III-V’s & Concentrators: Advanced III-V Concentrator Cells 10:30 - 12:00 PM (Lana’i 314)

60


AR

EA

4 P

RO

GR

AM

SU

MM

AR

Y

AREA 4 PROGRAM SUMMARY Monday, June 21Orals, Crystalline Silicon: Devices and Fabrication I 2:00 - 3:30 PM (Maui 316A/B) Tuesday, June 22Plenary, Crystalline Silicon 8:30 - 9:00 AM (Ballroom A/B) Posters, Crystalline Silicon: Device Fabrication and Characterization 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.b) Orals, Crystalline Silicon: Defect Passivation 1:30 - 3:00 PM (Maui 316A/B) Posters, Crystalline Silicon: Crystallization, Modelling and Characterization 3:30 - 5:00 PM (Kamehameha Exhibit Hall III.d) Wednesday, June 23Orals, Crystalline Silicon: Material and Device Characterization 1:30 - 3:00 PM (Maui 316A/B) Posters, Crystalline Silicon: Defect Passivation and Advanced Optics 3:30 - 5:00 PM (Kamehameha Exhibit Hall III.c) Thursday, June 24Orals, Crystalline Silicon: Contacts and Device Structures 8:30 - 10:00 AM (Maui 316A/B) Posters, Crystalline Silicon: Device Fabrication and Manufacturing 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.c) Orals, Crystalline Silicon: Feedstock and Crystallization 1:30 - 3:00 PM (Maui 316A/B) Orals, Crystalline Silicon: Surface Passivation 3:30 - 5:00 PM (Maui 316A/B) Friday, June 25Orals, Crystalline Silicon: Devices and Fabrication II 8:30 - 10:00 AM (Maui 316A/B) Orals, Crystalline Silicon: Manufacturing and New Concepts 10:30 - 12:00 PM (Maui 316A/B)


61


AR

EA

5 P

RO

GR

AM

SU

MM

AR

YAREA 5 PROGRAM SUMMARY Monday, June 21Orals, Amorphous, nc, & Film Silicon: Fundamental Film Properties 4:00 - 5:30 PM (Ni’ihau 312)

Tuesday, June 22Plenary, Amorphous, nc, & Film Silicon 9:00 - 9:30 AM (Ballroom A/B) Posters, Amorphous, nc, & Film Silicon: Devices, Modules, and Novel Concepts 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.c) Orals, Amorphous, nc, & Film Silicon: Light Management, TCOs and Alternative Multijunctions 1:30 - 3:00 PM (Lana’i 314)

Thursday, June 24Orals, Amorphous, nc, & Film Silicon: Processing Issues for Films and Devices 8:30 - 10:00 AM (Ni’ihau 312) Posters, Amorphous, nc, & Film Silicon: Fundamental Material Properties and Processing Issues 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.d) Orals, Amorphous, nc, & Film Silicon: Novel Concepts for Solar Cell Devices 1:30 - 3:00 PM (Ni’ihau 312)

Friday, June 25Orals, Amorphous, nc, & Film Silicon: Devices and Modules 10:30 - 12:00 PM (Moloka’i 315)

62


AR

EA

6 P

RO

GR

AM

SU

MM

AR

Y

AREA 6 PROGRAM SUMMARY Monday, June 21Orals, Organic Photovoltaics: Bulk Heterojunction Organic Solar Cells 2:00 - 3:30 PM (Moloka’i 315) Tuesday, June 22Plenary, Organic Photovoltaics 9:30 - 10:00 AM (Ballroom A/B) Posters, Organic Photovoltaics: Organic Photovoltaics 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.d) Wednesday, June 23Orals, Organic Photovoltaics: Small Molecule Based and Dye-Sensitized Solar Cells 1:30 - 3:00 PM (Lana’i 314) Posters, Organic Photovoltaics: Dye Sensitized Solar Cells and Nanostructured Oxide 3:30 - 5:00 PM (Kamehameha Exhibit Hall III.d) Thursday, June 24Orals, Organic Photovoltaics: Hybrid and Advanced Concept Organic Solar Cells 3:30 - 5:00 PM (Lana’i 314) Friday, June 25Orals, Organic Photovoltaics: Stability, Processing and Packaging of Organic Solar Cells 8:30 - 10:00 AM (Lana’i 314)


63


AR

EA

7 P

RO

GR

AM

SU

MM

AR

YAREA 7 PROGRAM SUMMARY Monday, June 21Orals, Space Technologies: Space Materials and Devices 2:00 - 3:30 PM (Lana’i 314)

Wednesday, June 23Plenary, Space Technologies 8:30 - 9:00 AM (Maui 316A/B) Posters, Space Technologies 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.b)

Thursday, June 24Orals, Space Technologies: Space Systems 8:30 - 10:00 AM (Lana’i 314)

Friday, June 25Orals, Space Technologies: Flight Performance and Environmental Effects 8:30 - 10:00 AM (Maui 316C)

64


AR

EA

8 P

RO

GR

AM

SU

MM

AR

Y

AREA 8 PROGRAM SUMMARY Monday, June 21Orals, PV Characterization: Defect States 4:00 - 5:30 PM (Lana’i 314)

Tuesday, June 22Posters, PV Characterization: Materials and Devices 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.e)

Wednesday, June 23Plenary, PV Characterization 9:00 - 9:30 AM (Maui 316A/B) Posters, PV Characterization: Module Characterization, Modeling and In-situ Process Control 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.c)

Thursday, June 24Orals, PV Characterization: Defects and Mulitjunction Device Performances 8:30 - 10:00 AM (Moloka’i 315) Orals, PV Characterization: Recombination Rate and Trap Measurements 1:30 - 3:00 PM (Lana’i 314)

Friday, June 25Orals, PV Characterization: Module and Module Material Characterization 10:30 - 12:00 PM (Maui 316C)


65


AR

EA

9 P

RO

GR

AM

SU

MM

AR

YAREA 9 PROGRAM SUMMARY Monday, June 21Orals, PV Modules & Systems: PV Modules and Materials 4:00 - 5:30 PM (Maui 316A/B)

Tuesday, June 22Joint Session Areas 9 & 10 Oral: High Penetration PV: Hawaiian Systems Experience 10:30 - 12:00 PM (Maui 316C) Orals, PV Modules & Systems: Inverters and Other BOS Components 1:30 - 3:00 PM (Moloka’i 315) Posters, PV Modules & Systems: Performance and Systems 3:30 - 5:00 PM (Kamehameha Exhibit Hall III.e)

Wednesday, June 23Plenary, PV Modules & Systems 9:30 - 10:00 AM (Maui 316A/B) Posters, PV Modules & Systems: Modules, Inverters and BOS Components 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.d) Orals, PV Modules & Systems: Integration of Grid Connected Systems 1:30 - 3:00 PM (Kaua’i 311)

Thursday, June 24Orals, PV Modules & Systems: Improving Performance of PV systems 3:30 - 5:00 PM (Moloka’i 315)

Friday, June 25Orals, PV Modules & Systems: Predictive Performance Modeling 8:30 - 10:00 AM (Moloka’i 315)

66


AR

EA

10

PR

OG

RA

M S

UM

MA

RY

AREA 10 PROGRAM SUMMARY Monday, June 21Panel Discussion, PV Velocity Forum: Moving the U.S. to High Penetration of PV 2:00 - 3:30 PM (Maui 316C) Programs Around the Globe 4:00 - 5:30 PM (Maui 316C)

Tuesday, June 22Joint Session Areas 9 & 10 Oral: High Penetration PV: Hawaiian Systems Experience 10:30 - 12:00 PM (Maui 316C)

Panel Presentations and Discussion: The Hawaii Clean Energy Initiative 1:30 - 3:00 PM (Maui 316C) Panel Presentations and Discussion: Jump-Starting Utility Markets for PV 3:30 - 5:00 PM (Maui 316C)

Wednesday, June 23Posters, PV Velocity Forum-Streamlining Paths to Markets 10:30 - 12:00 PM (Kamehameha Exhibit Hall III.e)

Panel Discussion, PV Velocity Forum: Supply and Economics in Thin-Film PV Materials 1:30 - 5:00 PM (Maui 316C) Thursday, June 24Gigawatt Scale Manufacturing 10:30 - 1:00 PM (Maui 316C) Panel Discussion, PV Velocity Forum: Women in PV 1:30 - 5:00 PM (Maui 316C)


67


O8 O9 O10BreakO2 O3 O5

Opening Session

O6 O7

Area 1 Plenary

Area 3 Plenary

O1

Keynote SpeechConf. PlenaryCherry Award

O10O2 O4

Break

Break8:30 PM9:00 PM

Exhibitors Reception5:30 - 8:30 PM

7:00 PM

8:00 PM

5:00 PM5:30 PM6:00 PM

4:00 PM

3:00 PM3:30 PM

1:30 PM2:00 PM

12:00 noon12:30 PM

10:00 AM10:30 AM

9:30 AMArea 2 Plenary

7:00 - 8:00 AMAuthors' Breakfast

Break8:00 AM8:30 AM

7:00 AM

Exhi

bits

Break

9:00 AM

MO

ND

AY

PR

OG

RA

M S

UM

MA

RY


AREA LEGEND

MONDAY PROGRAM SUMMARY

68


MO

ND

AY

AM

8:30 - 9:00 AM Ballroom A/B

Area 1: Plenary, Fundamentals & New Concepts Chair(s): Ryne Raffaelle, Yoshitaka Okada, Nicholas Ekins-Daukes

8:30 1

Experimental Measurement of Restricted Radiative Emission in Quantum Well Solar Cells. Jessica GJ Adams1, Warren Elder1, Paul N Stavrinou1, John S Roberts2, Geoff Hill2, Joseph G Tischler3, Robert J Walters3, Keith WJ Barnham1, Nicholas J Ekins-Daukes1 1Imperial College London, London, United Kingdom, 2University of Sheffield, Sheffield, United Kingdom, 3US Naval Research Laboratory, Washington, DC, USA


Area 2: Plenary, CIGS & CdTe Chair(s): Rommel Noufi

9:00 2

Production of Flexible CIGS PV at Global Solar Energy Jeff Britt, Scott Albright, U. Schoop, S. Schuler, W. Stoss, D. Verebelyi, Scott Wiedeman Global Solar Energy, Tucson, AZ, USA


Area 3: Plenary, III-V’s & Concentrators Chair(s): Frank Dimroth

9:30 3

The Current Status of the CPV Industry: System Performance and Cost Competitiveness Nancy Hartsoch CPV Consortium, Mountain View, CA, USA

10:00 - 10:30 AM Ala Halawai Concourse

Break


69


MO

ND

AY

AM10:30 - 12:30 PM Ballroom A/B

Opening Session, Keynote, Conference Plenary, and Cherry Award

Chair(s): Rob Walters

10:30 4

Opening Remarks Rob Walters 35 IEEE PVSC General Chair

10:35 5

Welcome Address James R. “Duke” Aiona, Jr. Lt. Governor of Hawaii

10:50 6

Presentation of EDS Celebrated Member Award to Nobel laureate, George Smith Renuka Jindal President EDS

11:05 7

State of the Solar Industry Address Rhone Resch President and CEO of SEIA

11:20 8

The Energy Challenge of Climate Stabilization Jae Edmonds Pacific Northwest National Laboratory, Joint Global Change Research Institute at the Univ. of Maryland

11:50 9

Cherry Award Presentation Antonio Luque Cherry Committee Chair

12:00 10

Multijunction Solar Cells - A Look Back and the Path Forward Richard King Spectrolab, Inc.

12:30 - 2:00 PM

Lunch on your own

70


2:00 - 3:30 PM Kaua’i 311

Area 2: Orals, CIGS & CdTe: Deposition & Characterization/Wide Band Gap & Novel

Materials-I Chair(s): Pete Sheldon, Sylvain Marsillac

2:00 11

Correlations of Photo-Electro-Thermal-Luminescent Imaging of Cu(In,Ga)Se2 with Device Performance, Defects, and Micro-Structural Properties Steven W. Johnston, Ingrid L. Repins, Rajalakshmi Sundaramoorthy, Kim M. Jones, Bobby To National Renewable Energy Laboratory, Golden, CO, USA

2:30 12

Monolithically Integrated CIGS Submodules Fabricated on Flexible Substrates Shogo Ishizuka, Takashi Yoshiyama, Kazuyuki Mizukoshi, Akimasa Yamada, Shigeru Niki National Institute of Advanced Industrial Science and Technology (AIST), Tsukuba, Japan

2:45 13

Latest Results of the German Joint Project - Flexible CIGSe Thin Film Solar Cells for Space Applications Kai Zajac1, Sebastian Brunner1, Christian A. Kaufmann2, Raquel Caballero2, Hans-Werner Schock2, Andreas Rahm3, Christian Scheit3, Hendrik Zachmann3, Friedrich Kessler4, Roland Würz4, Peter Schülke5 1HTS GmbH, Coswig, Germany, 2Helmholtz-Zentrum Berlin fuer Materialien und Energie (HZB), Berlin, Germany, 3Solarion AG, Leipzig, Germany, 4Zentrum fuer Sonnenenergie- und Wasserstoff-Forschung (ZSW), Stuttgart, Germany, 5Deutsches Zentrum für Luft- und Raumfahrt (DLR), Bonn, Germany

3:00 14

Dual – Electrochemical and Photochemical Shunt Passivation of CdTe Solar Cells Misle M Tessema1, Kristopher A Wieland2, Alvin D Compaan2, Dean M Giolando1 1University of Toledo, Department of Chemistry, Toledo, OH, USA, 2University of Toledo, Department of Physics and Astronomy, Toledo, OH, USA

3:15 15

Chemical Structure of Buried Interfaces in CdTe Thin Film Solar Cells Sujitra Pookpanratana1, Fatima Khan1, Yufeng Zhang1, Clemens Heske1, Lothar Weinhardt2, Marcus Baer3, Xiangxin Liu4, Naba R. Paudel4, Alvin D. Compaan4 1Dept. of Chemistry, University of Nevada, Las Vegas, Las Vegas, NV, USA, 2Experimentelle Physik VII, Universitaet Wuerzburg, Wuerzburg, Germany, 3Solar Energy Research, Helmholtz-Zentrum Berlin fuer Materialien und Energie GmbH, Berlin, Germany, 4Dept. of Physics and Astronomy, The University of Toledo, Toledo, OH, USA

MO

ND

AY

PM


71


2:00 - 3:30 PM Maui 316A/B

Area 4: Orals, Crystalline Silicon: Devices and Fabrication I

Chair(s): Ajeet Rohatgi, Jan Schmidt

2:00 16

Enabling Dielectric Rear Side Passivation for Industrial Mass Production by Developing Lean Printing-Based Solar Cell Processes Thomas Lauermann, Thomas Lüder, Sascha Scholz, Bernd Raabe, Giso Hahn, Barbara Terheiden University of Konstanz, Konstanz, Germany

2:30 17

Towards 19% Efficient Industrial PERC Devices Using Simultaneous Front Emitter and Rear Surface Passivation by Thermal Oxidation Sebastian Mack, Ulrich Jäger, Gero Kästner, Edgar A Wotke, Udo Belledin, Andreas Wolf, Ralf Preu, Daniel Biro Fraunhofer, Freiburg im Breisgau, Germany

2:45 18

Towards High Efficiency on Full Wafer a-Si:H/c-Si Heterojunction Solar Cells: 19.5% on 148 cm2 Delfina Munoz1, Anne Sophie Ozanne1, Samuel Harrison1, Adrien Danel1, Florent Souche1, Christine Denis1, Anthony Favier1, Nathalie Nguyen1, Pierre-Emmanuel Hickel2, Pierre Mur2, Thierry Salvetat2, Pierre-Jean Ribeyron1 1CEA-INES, 50 avenue du lac Léman, BP258 F-73375 Le Bourget du Lac, France, 2CEA-DRT/Leti, 17 Rue des Martyrs 38054 Grenoble, France

3:00 19

Excellent Rear Rassivation With 20 nm Uncapped Al2O3 Layer On Multi-Crystalline Silicon Cells: Industrialization Using ALD I. Cesar1, L.J. Geerligs1, P. Manshanden1, E. Bende1, E. Tois2, E. Granneman3, A.W. Weeber1 1ECN, Petten, Netherlands, 2ASM Microchemistry, Helsinki, Finland, 3Levitech, Almere, Netherlands

3:15 20

n-type Silicon - Enabling 20% in Industrial Production Stefan W. Glunz Fraunhofer ISE, Freiburg, Germany

MO

ND

AY

PM

72


2:00 - 3:30 PM Ni’ihau 312

Area 1: Orals, Fundamentals & New Concepts: Fundamental Mechanisms

Chair(s): Arthur Nozik, Stanko Tomic, Shuhei Yagi

2:00 21

Hot Carrier Solar Cells: Challenges And Recent Progress Martin A. Green1, Gavin Conibeer1, Dirk Koenig1, Santosh Shrestha1, Shujuan Huang1, Pasquale Aliberti1, Lara Treiber1, Robert Patterson1, Binesh P. Veettil1, Andy Hsieh1, Yu Feng1, Antonio Luque2, Antonio Marti2, P.G. Linares2, Jean-Francois Guillemoles3, Timothy Schmidt4 1ARC Photovoltaics Centre of Excellence, University of New South Wales, Sydney, Australia, 2Instituto de Energia Solar, Universidad Politecnica de Madrid, Madrid, Spain, 3Institute for Research and Development of Photovoltaic Energy (IRDEP), Paris, France, 4School of Chemistry, University of Sydney, Sydney, Australia

2:30 22

Hot Carrier Solar Cell Efficiency Simulation with Realistic Electronic Contact Arthur Le Bris, Jean-François Guillemoles IRDEP, Chatou, France

2:45 23

Advances in Quantum Dot Intermediate Band Solar Cells Antonio Luque, Antonio Marti Instituto de Energia Solar, Universidad Politecnica de Madrid, Madrid, Spain

3:00 24

Self-Consistent Drift-Diffusion Analysis of Intermediate Band Solar Cell (IBSC): Effect of Energetic Position of IB on Conversion Efficiency Katsuhisa Yoshida1,2, Yoshitaka Okada2, Nobuyuki Sano1 1Institute of Applied Physics, University of Tsukuba, Ibaraki, Japan, 2Research Center for Advanced Science and Technology (RCAST), The University of Tokyo, Tokyo, Japan

3:15 25

Fundamental Limit of Nanophotonic Light-trapping in Solar Cells Zongfu Yu, Aaswath Raman, Shanhui Fan Ginzton Lab, Stanford, CA, USA

MO

ND

AY

PM


73


2:00 - 3:30 PM Moloka’i 315

Area 6: Orals, Organic Photovoltaics: Bulk Heterojunction Organic Solar Cells

2:00 26

Determination of Recombination Mechanisms in Organic Solar Cells Robert Street1, Megan Schoendorf1, Sarah Cowan2, Alan Heeger2 1Palo Alto Research Center, Palo Alto, CA, USA, 2Center for Polymers and Organic Solids, Santa Barbara, CA, USA

2:30 27

Morphology-Dependent Short-Circuit Current in Bulk Heterojunction Solar cell Biswajit Ray, Pradeep R Nair, Muhammad A. Alam Department of Electrical and Computer Engineering, Purdue University, West lafayette, IN, USA

2:45 28

Efficient Bulk Heterojunction Solar Cells Incorporating Carbon Nanotubes and with Electron Selective Interlayer Golap Kalita, Koichi Wakita, Masayoshi Umeno Chubu University, Kasugai-shi, Japan

3:00 29

Understanding the Role of Single Walled Carbon Nanotubes in Improving the Efficiency of P3HT:PCBM Solar Cells using Impedance Spectroscopy and Morphological Studies Arun Tej Mallajosyula, S. Sundar Kumar Iyer, Baquer Mazhari Department of Electrical Engineering and Samtel Centre for Display Technologies, Indian Institute of Technology Kanpur, Kanpur, India

3:15 30

Optimization of Organic Photovoltaic Devices Using Tuned Mixed Metal Oxide Contact Layers Joseph J. Berry1, K. Xerxes Steirer2, N. Edwin Widjonarko3, Ajaya K. Sigdel4, Matthew T. Lloyd1, David S Ginley1, Dana C. Olson1 1National Renewable Energy Laboratory, Golden, CO, USA, 2Colorado School of Mines, Golden, CO, USA, 3University of Colorado at Boulder, Boulder, CO, USA, 4University of Denver, Denver, CO, USA

MO

ND

AY

PM

74


MO

ND

AY

PM

2:00 - 3:30 PM Lana’i 314

Area 7: Orals, Space Technologies: Space Materials and Devices

Chair(s): Bernie Carpenter, Henry Brandhorst

2:00 31

Development of a Four Sub-cell Inverted Metamorphic Multi-Junction (IMM) Highly Efficient AM0 Solar Cell Arthur Cornfeld, Daniel Aiken, Benjamin Cho, Vance Ley, Paul Sharps, Mark Stan, Tansen Varghese Emcore Corporation, Albuquerque, NM, USA

2:15 32

IMM Experimentation in the Next Frontier: Emcore’s Participation in the MISSE-8 Program Benjamin Cho1, Richard Lutz1, James Pappan1, Eric Downard1, Arthur Cornfeld1, Navid Fatemi1, Mark A Stan1, Paul Sharps1, Chad Su2, Scott Billets2, Steve Gasner2, Alex Howard3 1Emcore Photovoltaics, Albuquerque, NM, USA, 2Lockheed Martin Space Systems Company, Sunnyvale, CA, USA, 3Air Force Research Laboratory, Albuquerque, NM, USA

2:30 33

Path to a Drop-in Replacement for Current Technologies with the 33% Large-Area IMM Cell Daniel Chumney, Daniel Aiken, Benjamin Cho, Arthur Cornfeld, Jacqueline Diaz, Vance Ley, Jack Mittman, Fredrick Newman, Paul Sharps, Mark Stan, Tansen Varghese Emcore, Albuquerque, NM, USA

2:45 34

Development of radiation hard Ga0.5In0.5P/Ga0.99In0.01As/Ge Space Solar Cells with Multi Quantum Wells René Kellenbenz1, Raymond Hoheisel1, Peter Kailuweit1, Wolfgang Guter2, Frank Dimroth1 1Fraunhofer ISE, Freiburg, Germany, 2AZURSPACE Solar Power GmbH, Heilbronn, Germany

3:00 35

Development of Advanced Inverted Metamorphic Space Solar Cells at Spectrolab Joseph C. Boisvert, Daniel C. Law, Richard R. King, Dhananjay M. Bhusari, Xing-Quan Liu, Abdallah Zakaria, Shoghig Mesropian, Diane C. Larrabee, Robyn L. Woo, Andreea Boca, Kenneth M. Edmondson, Dimtri D. Krut, David M. Peterson, Kaveh Rouhani, Bartlomiej J. Benedikt, Nasser H. Karam Boeing Spectrolab, Sylmar, CA, USA

3:15 36

JAXA’s Strategy for Development of High Performance Space Photovoltaics Mitsuru Imaizumi1, Masato Takahashi1, Tatsuya Takamoto2 1JAXA, Tsukuba, Japan, 2SHARP, Yamatokoriyama, Japan


75


MO

ND

AY

PM2:00 - 3:30 PM Maui 316C

Area 10: Panel Discussion, PV Velocity Forum: Moving the U.S. to High Penetration of PV

Chair(s): James Prendergast

37 NIST Workshop on PV Measurements Kris Bertness NIST

38 IEEE PV Codes and Standards Richard DeBlasio NREL

39 DOE EERE SETP Program John Lushetsky U.S. DOE

40 NSF Innovation in Photovoltaics Greg Rorrer National Science Foundation

3:30 - 4:00 PM Ala Halawai Concourse

Break

4:00 - 5:30 PM Maui 316C

Area 10: Programs Around the Globe Chair(s): Ryne Raffaelle, David Wilt

4:00 41

Photovoltaics Development and Applications in China Shenghong Ma China Academy of Science

4:20 42

The Photovoltaic Technology Incubator Project Kaitlyn VanSant1, Martha Symko-Davies1, Richard Mitchell1, Brian Keyes1, Harin Ullal1, Bolko von Roedern1, Scott Stephens2 1National Renewable Energy Laboratory, Golden, CO, USA, 2Department of Energy, Washington, DC, USA

4:40 43

PV trends in Japan - Progress of the PV market by new support measures Izumi KAIZUKA, Takashi OHIGASHI, Hiroshi MATSUKAWA, Osamu IKKI RTS Corporation, Tokyo, Japan

5:00 44

U. S. Air Force Program for research on Advanced High Performance Photovoltaic Power John Merrill Kirkland Air Force Base

76


4:00 - 5:30 PM Ni’ihau 312

Area 5: Orals, Amorphous, nc, & Film Silicon: Fundamental Film Properties

Chair(s): David Bobela, Sumit Agarwal

4:00 45

Staebler-Wronski Defects: Creation Efficiency, Stability, and Effect on a-Si:H Cell Degradation Paul Stradins National Renewable Energy Laboratory, Golden, CO, USA

4:30 46

Dependence of Carrier Recombination in Protocrystalline a-Si:H Films and Cells on Their Different Light Induced Gap States Christopher R Wronski1, Jindong Deng2, Xinwei Niu3, Arno H M Smets4 1Pennsylvania State University, University Park, PA, USA, 2IBM Electronics, Essex Junction, VT, USA, 3Cint Solar (Zhejang), Hangzhou, China, 4DIMS Delft University of Technology, Delft, Netherlands

4:45 47

Voc-Limiting Recombination Mechanisms in thin film silicon on glass solar cells Johnson Wong1, Jialiang Huang1, Mark Keevers2, Martin Green1 1University of New South Wales, Sydney, Australia, 2CSG Solar Pty Ltd, Sydney, Australia

5:00 48

On the Effect of the Amorphous Silicon Microstructure on the Grain Size of Poly-Crystalline Silicon Kashish Sharma, Annalisa Branca, Andrea Illiberi, M Creatore, MCM van de Sanden Einhoven University of Technology, Eindhoven, Netherlands

5:15 49

Microstructural Evolution in Si1-xGex:H Thin Films for Photovoltaic Applications Nikolas J. Podraza1, David B. Saint John2, Christopher R. Wronski1, Elizabeth C. Dickey2, Robert W. Collins3 1Department of Electrical Engineering, The Pennsylvania State University, University Park, PA, USA, 2Department of Materials Science and Engineering, The Pennsylvania State University, University Park, PA, USA, 3Center for Photovoltaics Innovation and Commercialization, The University of Toledo, Toledo, OH, USA

MO

ND

AY

PM


77


MO

ND

AY

PM4:00 - 5:30 PM Kaua’i 311

Area 2: Orals, CIGS & CdTe: Modules, Manufacturing, and Reliability

Chair(s): Markus Gloeckler, Scott Wiedeman

4:00 50

Achievement of 16 % Milestone with 30 cm x 30 cm-sized CIS-based Thin-film Submodules Yoshiyuki Chiba, S Kijima, H Sugimoto, Y Kawaguchi, M Nagahashi, T Morimoto, T Yagioka, T Miyano, T Aramoto, Y Tanaka, H Hakuma, S Kuriyagawa, K Kushiya Showa Shell Sekiyu, Kanagawa, Japan

4:30 51

Flexible Cells and Modules Produced using Roll-to-Roll Electroplating Approach Mustafa Pinarbasi, Serdar Aksu, James Freitag, Thomas Boone, Howard Zolla, Jorge Vasquez, Deepak Nayak, Eric Lee, Tony Wang, Burak Metin SoloPower Inc., San Jose, CA, USA

4:45 52

Copper Indium Gallium Selenide Photovoltaic Modules Manufactured by Reactive Transfer Dingyuan Lu, Baosheng Sang, Yuepeng Deng, Billy J. Stanbery, Louay Eldada HelioVolt Corporation, 6301-8 E Stassney Lane, Austin, TX, USA

5:00 53

CIGS P1, P2 and P3 Laser Scribing with an Innovative Fiber Laser Richard Murison1, Corey Dunsky2, Matt Rekow1, Craig Dinkel3, John Pern4, Lorelle Mansfield4, Tullio Panarello1, Suwas Nikumb3 1PyroPhotonics Lasers Inc., Dollard-des-Ormeaux, QC, Canada, 2Aeos Consulting Inc., Los Gatos, CA, USA, 3NRC Canada, London, ON, Canada, 4National Renewable Energy Laboratory, Golden, CO, USA

5:15 54

Driving Down CIGS Cost of Ownership with High Volume Thermal Deposition Systems John C Patrin1, Chad Conroy1, Jian-gang Weng1, Doug Brown2, Ken Pfeiffer2, David Fobare3, Jennifer Novak3, Jeff Amadon3, Dave Metacarpa3 1Veeco Instruments, St. Paul, MN, USA, 2Veeco Solar Equipment, Lowell, MA, USA, 3Veeco Solar Process Development Center, Clifton Park, NY, USA

78


MO

ND

AY

PM

4:00 - 5:30 PM Moloka’i 315

Area 3: Orals, III-V’s & Concentrators: III-V Concentrator Solar Cells and Receivers

Chair(s): John Geisz, Tatsuya Takamoto

4:00 55

Status of 40% Production Efficiency Concentrator Cells at Spectrolab Russ Jones, Peter Hebert, Peichen Pien, Richard R King, Dhananjay Bhusari, Randolph Brandt, Omar Al Taher, Christopher M Fetzer, James H Ermer, Andreea Boca, Diane C Larrabee, Xiang-Quan Liu, Nasser Karam Spectrolab, Inc, Sylmar, CA, USA

4:15 56

Development, Cost Reduction and Customized Design of Industrial Concentrator Solar Cells with Efficiencies Approaching 40% and Above Wolfgang Guter1, Werner Bensch1, Richard Kern1, Wolfgang Köstler1, Matthias Meusel1, Gerhard Strobl1, Sascha van Riesen2, Tobias Gerstmaier2, Andreas Gombert2, Frank Dimroth3, Andreas W. Bett3 1AZUR SPACE Solar Power GmbH, Heilbronn, Germany, 2Concentrix Solar GmbH, Freiburg, Germany, 3Fraunhofer ISE, Freiburg, Germany

4:30 57

Simulation of Nonuniform Irradiance in Multijunction IIIV Solar Cells Jerry M Olson National Renewable Energy Lab, Golden, CO, USA

4:45 58

Self-assembled SiO2 Particle Coating on 2-layer Anti-reflection Films for Efficiency Enhancement of GsAs PV Cells Kentaroh Watanabe1, Akio Higo1, Masakazu Sugiyama2, Yoshiaki Nakano1 1Recearch Center for Advanced Science and Technology, University of Tokyo, Meguro-ku, Tokyo, Japan, 2Department of Electrical Engineering and Information Systems, School of Engineering, University of Tokyo, Bunkyo-ku, Tokyo, Japan

5:00 59

EMCORE Receivers for CPV System Developers James S. Foresi, Lei Yang, John Nagyvary, Phil Blumenfeld, Greg Flynn, Chris Dempsey EMCORE Corporation, Albuquerque, NM, USA

5:15 60

Heat Transfer Modeling of Multijunction Concentrator Solar Cell Assemblies Using Finite Difference Techniques Hector L. Cotal, John S. Frost Spectrolab, Inc, Symar, CA, USA


79


MO

ND

AY

PM4:00 - 5:30 PM Lana’i 314

Area 8: Orals, PV Characterization: Defect States Chair(s): Robert Collins, Richard Ahrenkiel

4:00 61

Novel Applications of Near-field Scanning Optical Microscopy: Microluminescence from Local Junction Breakdown in Solar Cells Manuel J. Romero National Renewable Energy Laboratory, Golden, CO, USA

4:30 62

Selective Measurement of Photovoltaic Interfaces with Optical Second Harmonic Generation Charles Teplin1, Long He2, Howard Branz1, Matt Page1, Eugene Iwaniczko1, Charles Rogers2 1NREL, Golden, CO, USA, 2University of Colorado at Boulder, Boulder, CO, USA

4:45 63

Diffused Junctions in Multicrystalline Si Solar Cells Studied by Complementary Scanning Probe Microscopy and Scanning Electron Microscopy Techniques Jennifer T. Heath1,2, Chun-Sheng Jiang2, Mowafak M Al-Jassim2 1Linfield College, McMinnville, OR, USA, 2National Renewable Energy Laboratory, Golden, CO, USA

5:00 64

Scanning Tunneling Microscopy as a Probe of Defects in CuInSe2 Marie Mayer2, Pamela Martin1, Joseph Lyding3, Angus Rockett1 1Department of Materials Science and Engineering, University of Illinois, Urbana, IL, USA, 2Department of Materials Science and Engineering, University of California at Berkeley, Berkeley, CA, USA, 3Department of Electrical and Computer Engineering, University of Illinois, Urbana, IL, USA

5:15 65

Defect Characterization by Admittance Spectroscopy Techniques based on Temperature-Rate Duality Jian V. Li, Steve W. Johnston, Yanfa Yan, Aaron J. Ptak, Ingrid L. Repins, Dean H. Levi National Renewable Energy Laboratory, Golden, CO, USA

80


MO

ND

AY

PM

4:00 - 5:30 PM Maui 316A/B

Area 9: Orals, PV Modules & Systems: PV Modules and Materials

Chair(s): Scott Norquist, Terry Jester

4:00 66

Test-to-Failure of Crystalline Silicon Modules Peter Hacke, Kent Terwilliger, David Trudell, Nick Bosco, Steve Johnston, Sarah Kurtz National Renewable Energy Laboratory, Golden, CO, USA

4:30 67

Failure Analysis of Module Design Qualifications Testing - III: 1997-2005 vs. 2005-2007 vs. 2007-2009 Govindasamy Tamizhmani, Bo Li, Todd Arends, Joseph Kuitche, Bindhu Raghuraman, William Shisler, Kent Farnsworth, Arseniy Voropayev TUV Rheinland PTL, Tempe, AZ, USA

4:45 68

Evaluation and Modeling of Edge Seal Materials for Photovoltaic Applications Michael Kempe, Matthew Reese, Arrelaine Dameron, Thomas Moricone NREL, Golden, CO, USA

5:00 69

Creep in Photovoltaic Modules: Examining the Stability of Polymeric Materials and Components David C Miller, Michael D Kempe, Stephen H Glick, Sarah R Kurtz National Renewable Energy Laboratory, Golden, CO, USA

5:15 70

An Optical Comparison of Silicone and EVA Encapsulants under Various Spectra Keith R. McIntosh1, James N. Cotsell1, Ann W. Norris2, Nick E. Powell2, Barry M. Ketola2 1Australian National University, Canberra, Australia, 2Dow Corning Corporation, Midland, MI, USA

5:30 - 8:30 PM Exhibition

Exhibitor’s Reception


81


TU

ES

DA

Y P

RO

GR

AM

SU

MM

AR

Y


AREA LEGEND

TUESDAY PROGRAM SUMMARY

kaerB

P4

Break

P5

P1 P9P4Break

O10

6:00 - 9:00 PM

8:30 PM9:00 PM

7:00 PM

8:00 PM

5:00 PM5:30 PM6:00 PM Cherry Reception

P8

P2 P3

O10O5 O9

P6

Break

4:00 PM

3:00 PM3:30 PM

1:30 PM2:00 PM

12:00 noon12:30 PM

O1 O2 O4

10:00 AM10:30 AM

9:30 AM

kaerB

Area 4 PlenaryArea 5 PlenaryArea 6 Plenary

8:00 AM8:30 AM

7:00 AM Authors' Breakfast7:00 - 8:00 AMBreak

O10

Exhi

bits

O9

9:00 AM

82


TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

TUESDAY POSTER PRESENTATIONS

Kamehameha Exhibit Hall

AM POSTER SESSION 10:30 - 12:00 PM

Area 4: Posters, Crystalline Silicon: Device Fabrication and Characterization

Chair(s): Matthias Hörteis, Francois Henley

Area 5: Posters, Amorphous, nc, & Film Silicon: Devices, Modules, and Novel Concepts

Chair(s): Hitoshi Sai, Paul Stradins

Area 6: Posters, Organic Photovoltaics: Organic Photovoltaics

Area 8: Posters, PV Characterization: Materials and

Devices Chair(s): Steve Johnston, Jennifer Heath

PM POSTER SESSION 3:30 - 5:00 PM

Area 1: Posters, Fundamentals & New Concepts: Nanostructures

Chair(s): Ryne Raffaelle, Yoshitaka Okada, Nicholas Ekins-Daukes

Area 2: Posters, CIGS & CdTe: CdTe and Other Materials

Chair(s): Ayodhya Tiwari, Tim Gessert

Area 3: Posters, III-V’s & Concentrators: III-V Concentrator Cells

Chair(s): J. Ermer, W. Guter

Area 4: Posters, Crystalline Silicon: Crystallization, Modelling and Characterization

Chair(s): Jianming Fu, Daniel Kray

Area 9: Posters, PV Modules & Systems: Performance and Systems

Chair(s): Katie Brown, Terry Jester


83


TU

ES

DA

Y A

M8:30 - 9:00 AM Ballroom A/B

Area 4: Plenary, Crystalline Silicon Chair(s): Klaus Weber

8:30 71

Gen III: Improved Performance at Lower Cost Peter J. Cousins, David D. Smith, Hsin-Chiao Luan, Jane Manning, Tim D. Dennis, Ann Waldhauer, Karen E. Wilson, Gabriel Harley, William P. Mulligan SunPower Corp., San Jose, CA, USA


Area 5: Plenary, Amorphous, nc, & Film Silicon Chair(s): Arno Smets

9:00 72

Thin-Film Polycrystalline Si Solar Cells with Low Intragrain Defect Density made via Laser Crystallization and Epitaxial Growth Dries Van Gestel1, Monica Deep2, P.C. van der Wilt2, Yu Qiu1, Ivan Gordon1, James S. Im2, Jef Poortmans1 1IMEC, Leuven, Belgium, 2Columbia University, New York, NY, USA


Area 6: Plenary, Organic Photovoltaics Chair(s): Dave Ginley

9:30 73

Progress and Future Challenges for the Organic Photovoltaics Industry Alessandro Zedda, Alan Heeger Konarka Technologies Inc., Lowell, MA, USA

10:00 - 10:30 AM Exhibit Hall

Break

84


TU

ES

DA

Y A

M

10:30 - 12:00 PM Maui 316C

Joint Session Areas 9 & 10 Oral: High Penetration PV: Hawaiian Systems Experience

Chair(s): Elaine Ulrich, Maria Tome

10:30 74

Lanai High-Density Irradiance Sensor Network for Characterizing Solar Resource Variability of MW-Scale PV System Scott S. Kuszmaul1, Abraham Ellis1, Joshua Stein1, Lars Johnson2 1Sandia National Laboratories, Albuquerque, NM, USA, 2SunPower Corporation, Richmond, CA, USA

11:00 75

Permitting a Large-Scale PV Application Christopher Lovvorn Castle & Cooke Resorts

11:15 76

Methods of Integrating a High Penetration Large Scale Photovoltaic Power Plant into a Micro Grid Lauren Nelson, Carl Lenox, Lars Johnson, Robert Johnson SunPower Corp., Richmond, CA, USA

11:30 77

Hawaii Electric Perspective

11:45 78

Kauai Electric Cooperative Perspective Steven Rymsha

10:30 - 12:00 PM Kamehameha Exhibit Hall

AM Poster Session: Areas 4, 5, 6, & 8

SEE PAGE 133-146 FOR POSTER PRESENTATION LISTINGS.

12:00 - 1:30 PMLunch on your own


85


TU

ES

DA

Y P

M1:30 - 3:00 PM Lana’i 314

Area 5: Orals, Amorphous, nc, & Film Silicon: Light Management, TCOs and Alternative Multijunctions

Chair(s): XiXiang Xu, Miro Zeman

1:30 79

Impact of Front and Rear-Side Texturing on Light Trapping in Thin-Film Silicon Solar Cells Hitoshi Sai, Michi Kondo National Institute of Advanced Industrial Science and Techonology, Tuskuba, Japan

2:00 80

Comprehensive Experimental and Numerical Optimization of Surface Morphology of Transparent Conductive Oxide Films for Tandem Thin Film Photovoltaic Cells Mukul Agrawal1, Michel Frei1, Yashraj Bhatnagar1, Tobias Repmann2, Karin Witting2, Jürgen Schroeder2, Chris Eberspacher1 1Applied Materials, Santa Calara, CA, USA, 2Applied Materials, Alzenau, Germany

2:15 81

Electrodeposition of Low-resistivity Y-doped ZnO and its Thermal Stability Xiaofei Han1, Meng Tao2 1Department of Materials Science and Engineering,University of Texas as Arlington, Arlington, TX, USA, 2Department of Electrical Engineering, University of Texas as Arlington, Arlington, TX, USA

2:30 82

Application of Microcrystalline Si1-xGex Infrared Absorbers in Triple Junction Solar Cells Takuya Matsui1, Haijun Jia1, Michio Kondo1, Kouichi Mizuno2, Shigenori Tsuruga3, Satoshi Sakai3, Yoshiaki Takeuchi4 1Research Center for Photovoltaics, National Institute of Advanced Industrial Science and Technology (AIST), Tsukuba, Japan, 2Nagasaki R. &D. Center, Mitsubishi Heavy Industries, Ltd. (MHI), Nagasaki, Japan, 3Advanced Technology Research Center, MHI, Yokohama, Japan, 4Solar Power System Business Unit, MHI, Isahaya, Japan

2:45 83

Silicon Based Multijunction Solar Cells with Wide-Gap a-Si1-xCx:H Top Cell: Experimental and Numerical Approaches Ihsanul A Yunaz1, Shinsuke Miyajima1, Makoto Konagai1,2 1Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan, 2Photovoltaics Research Center (PVREC), Tokyo Institute of Technology, Tokyo, Japan

86


TU

ES

DA

Y P

M

1:30 - 3:00 PM Kaua’i 311

Area 2: Orals, CIGS & CdTe: Device Properties and Modeling/Characterization

Chair(s): Jim Sites, Takashi Minemoto

1:30 84

Assessing Possibilities & Limits for Thin Film Solar Cells David Cahen Weizmann Institute of Science, Rehovot, Israel

2:00 85

Device Characterization of (AgCu)(InGa)Se2 Solar Cells William Shafarman1, Gregory Hanket1, Jonathan Boyle1, Christopher Thompson1, Peter Erslev2, J. David Cohen2 1Institute of Energy Conversion, University of Delaware, Newark, DE, USA, 2Department of Physics, University of Oregon, Eugene, OR, USA

2:15 86

CIGS Thin Film Solar Cells on Polyimide Foils Tokio Nakada, Taku Kuraishi, Taku Inoue, Takahiro Mise Aoymama Gakuin University, Sagamihara, Japan

2:30 87

Comparisons of CdS/CdTe Superstrate and Substrate Devices Fabricated with a ZnTe:Cu Contact Interface Timothy A. Gessert, Ramesh G. Dhere, Joel N. Duenow, Matthew R. Young National Renewable Energy Laboratory, Golden, CO, USA

2:45 88

The Effect of CdTe Deposition Temperature on Device Properties of Different TCOs and Glass Substrates Ramesh Dhere1, Max Bonnet-Eymard2, Joel Duenow1, Helio Moutinho1, Jien Li1, Marty Scott1, David Albin1, Tim Gessert1 1NREL, Golden, CO, USA, 2Saint-Gobain Herzogenrath Research Center, Herzogenrath, Germany


87


TU

ES

DA

Y P

M1:30 - 3:00 PM Maui 316A/B

Area 4: Orals, Crystalline Silicon: Defect Passivation Chair(s): Kazuo Nakajima, Gianluca Coletti

1:30 89

Impact of Defect Type on Hydrogen Passivation Effectiveness in Multicrystalline Silicon Solar Cells Mariana I. Bertoni1, Steve Hudelson1, Bonna K. Newman1, Sarah Bernardis1, David P. Fenning1, Harold F.W. Dekkers2, Emanuele Cornagliotti2, Annika Zuschlag3, Gabriel Micard3, Giso Hahn3, Gianluca Coletti4, Barry Lai5, Tonio Buonassisi1 1Massachusetts Institute of Technology, Cambridge, MA, USA, 2IMEC vzw., Leuven, Belgium, 3University of Konstanz, Konstanz, Germany, 4ECN Solar Energy, Petten, Netherlands, 5Advanced Photon Source, Argonne, IL, USA

2:00 90

µXRF Investigations on the Influence of Solar Cell Processing Steps on Iron and Copper Precipitates in Multicrystalline Silicon Annika S. Zuschlag, Sibylle Ohl, Humphrey Morhenn, Johannes Junge, Jan Ebser, Sven Seren, Giso Hahn University of Konstanz, Konstanz, Germany

2:15 91

Direct Comparison of Boron Phosphorus and Aluminium Gettering of Iron in Crystalline Silicon Sieu-Pheng Phang, Daniel H. Macdonald School of Engineering, The Australian National University, Canberra, Australia

2:30 92

Stress and Temperature Coupling Effects on Dislocation Density Reduction in Multicrystalline Silicon Sergio Castellanos, Mariana I. Bertoni, Michelle Vogl, Alexandria Fecych, Tonio Buonassisi Dept. Mechanical Engineering, Massachusetts Institute of Technology, Cambridge, MA, USA

2:45 93

Influence of Emitter Profile Characteristic on Thermal Stability, Passivation Quality and Bulk Lifetime of a:Si/SiNX Passivated Boron Emitters Michael Andreas Kessler1, Sebastian Gatz1, Pietro Altermatt2, Nils-Peter Harder1,3, Rolf Brendel1,2 1Institute of Solar Energy Research Hameln (ISFH), Hameln, Germany, 2Institute of Solid-State Physics, University of Hannover, Hannover, Germany, 3Institute of Electronic Materials and Device, University of Hannover, Hannover, Germany

88


TU

ES

DA

Y P

M

1:30 - 3:00 PM Ni’ihau 312

Area 1: Orals, Fundamentals & New Concepts: Multiple Quantum Well or Dot Solar Cells

Chair(s): Seth Hubbard, Samuel Mao, Denis Guimard

1:30 94

Electroluminescence Spectroscopy of InAs/GaAs Quantum Dot Enhanced Solar cells as a Function of Temperature and Bias Christopher Bailey1, Joanne Oakvath1, Stephen Polly1, David Forbes1, Seth M. Hubbard1, Ryne Raffaelle2 1Rochester Institute of Technology, Rochester, NY, USA, 2National Renewable Energy Laboratory, Golden, CO, USA

2:00 95

Third Generation Photovoltaics: Multiple Exciton Generation in Colloidal Quantum Dots, Quantum Dot Arrays, and Quantum Dot Solar Cells Arthur J Nozik1,2, Matt C Beard1, Joey M Luther1, Aaron Midgett2, Octavi Semonin2, Justin C Johnson2 1NREL, Golden, CO, USA, 2University of Colorado, Boulder, CO, USA

2:15 96

How Shall We Put Multiple Quantum Wells in p-i-n Structure for Efficiency Enhancement? Sugiyama Masakazu1, Yunpeng Wang2, Soohyeck Choi1, Yu Wen2, Yoshiaki Nakano2 1Department of Electrical Engineering and Information Systems, School of Engineering, the University of Tokyo 7-3-1 Hongo, Bunkyo-ku,, Tokyo, Japan, 2Research Center for Advanced Science and Technology, the University of Tokyo, Tokyo, Japan

2:30 97

Modeling of 1 eV Dilute Nitride Multi-Quantum Well Solar Cells Gopi Krishna Vijaya, Andenet Alemu, Alex Freundlich Photovoltaics and Nanostructures Laboratory, Center for Advanced Materials, University of Houston, Houston, TX, USA

2:45 98

Strain-Compensated Multiple Stepped Quantum Wells (SC-MSQWs) Cell for Enhanced Spectral Response and Carrier Transport Yu Wen1, Yunpeng Wang1, Masakazu Sugiyama2, Yoshiaki Nakano1 1Research Center for Advanced Science and Technology,University of Tokyo, Tokyo, Japan, 2Department of Electrical Engineering and Information Systems, School of Engineering,University of Tokyo, Tokyo, Japan


89


TU

ES

DA

Y P

M1:30 - 3:00 PM Moloka’i 315

Area 9: Orals, PV Modules & Systems: Inverters and Other BOS Components

Chair(s): Ward Bower, Pierre Verlinden

1:30 99

Simulation of PV Systems with Power Optimizers and Distributed Power Electronics Perry I Tsao National Semiconductor, Santa Clara, CA, USA

2:00 100

Partially Shaded Operation of Multi-String PV Systems Chris Deline National Renewable Energy Laboratory, Golden, CO, USA

2:30 101

Energy-Efficient Cost-Effective Inverter Configuration for Residential Photovoltaic Systems Omar EL Bassiouny, Sairaj Dhople, Ali Davoudi, Patrick Chapman University of Illinois, Champaign, IL, USA

2:45 102

Firmware Implementation of An Adaptive Solar Cell Maximum Power Point Tracking Based on PSoC Wu-Shun Jwo, Chia-Chang Tong, Chi-Jui Chao Chienkuo Technology University, Changhua City, Taiwan

1:30 - 3:00 PM Maui 316C

Area 10: Panel Presentations and Discussion: The Hawaii Clean Energy Initiative

Moderator: Ted Peck

Hawaii State Representative Hermina Morita

Chairman Hawaii Public Utility Commission Carl Caliboso

Hawaii Solar Energy Industry AssociationMark Duda

Hawaii Electric Company (HECO)Scott Seu

3:00 - 3:30 PM Exhibit Hall

Break

90


TU

ES

DA

Y P

M

3:30 - 5:00 PM Maui 316C

Area 10: Panel Presentations and Discussion: Jump-Starting Utility Markets for PV

Chair(s): Carol Tombari

106 Market Issues and Policy Approaches Chris Cook Interstate Renewable Energy Council

107 Jump-Starting Markets Through Regulatory Incentives Kris Mayes Arizona Corporation Commission

108 Jump-Starting Markets Through Public Policy Initiatives Rhone Resch President, Solar Energy Industry Association


PM Poster Session: Areas 1, 2, 3, 4, & 9

SEE PAGE 146-163 FOR POSTER

PRESENTATION LISTINGS.

6:00 - 9:00 PM Lagoon Lawn at the Hilton

Cherry Reception & High School Awards


91


WED

NES

DA

Y P

RO

GR

AM

SU

MM

AR

Y


AREA LEGEND

WEDNESDAY PROGRAM SUMMARY

kaerB

Break

P3Break

Area 1 Late Night7:00 - 9:00 PM

P6

8:30 PM9:00 PM

7:00 PM

8:00 PM

P4

5:00 PM5:30 PM6:00 PM

P1

P8

O10

9P

O1

P7

O3 O4 O9

P2 P10

4:00 PM

3:00 PM3:30 PM

Break

O61:30 PM2:00 PM

12:00 noon12:30 PM

10:00 AM10:30 AM

9:30 AM

kaerB

Break

Area 8 PlenaryArea 9 Plenary

Area 7 Plenary

8:00 AM8:30 AM

7:00 AMAuthors' Breakfast7:00 - 8:00 AM

Exhi

bits

O2

9:00 AM

92


WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

WEDNESDAY POSTER PRESENTATIONS



Area 2: Posters, CIGS & CdTe: CIGS I and TCOs Chair(s): Harin Ullal, John Perkins

Area 7: Posters, Space Technologies Chair(s): Bernie Carpenter, David Chapman

Area 8: Posters, PV Characterization: Module Characterization, Modeling and In-situ Process

Control Chair(s): Sylvain Marsillac, Yoshihiro Hishikawa

Area 9: Posters, PV Modules & Systems: Modules, Inverters and BOS Components

Chair(s): Ward Bower

Area 10: Posters, PV Velocity Forum-Streamlining Paths to Markets

Chair(s): John Benner

PM POSTER SESSION 3:30 - 5:00 PM

Area 1: Posters, Fundamentals & New Concepts: Novel Mechanisms and Materials

Chair(s): Ryne Raffaelle, Yoshitaka Okada, Nicholas Ekins-Daukes

Area 3: Posters, III-V’s & Concentrators: Concentrator Systems

Chair(s): Bob Cart, Frank Dimroth

Area 4: Posters, Crystalline Silicon: Defect Passivation and Advanced Optics

Chair(s): Mariana Bertoni, Jan Benick

Area 6: Posters, Organic Photovoltaics: Dye Sensitized Solar Cells and Nanostructured Oxide


93


WED

NES

DA

Y A

M8:30 - 9:00 AM Maui 316A/B

Area 7: Plenary, Space Technologies Chair(s): Alex Howard, Mitsuru Imaizumi, Carsten Baur

8:30109

World’s Highest Efficiency Triple-junction Solar Cells Fabricated by Inverted Layers Transfer Process Tatsuya Takamoto1, Takaaki Agui1, Atsushi Yoshida1, Katsuya Nakaido1, Hiroyuki Juso1, Kazuaki Sasaki1, Kazuyo Nakamura1, Hiroshi Yamaguchi1, Tomoya Kodama1, Hidetoshi Washio1, Mitsuru Imaizumi2, Masato Takahashi2 1Sharp, Nara, Japan, 2Japan Aerospace Exploration Agency, Ibaraki, Japan

9:00 - 9:30 AM Maui 316A/B

Area 8: Plenary, PV Characterization Chair(s): Angus Rockett

9:00 110

Electron Backscatter Diffraction: Exploring the Microstructure in Cu(In,Ga)(S,Se)2 and CdTe Thin-Film Solar Cells Daniel Abou-Ras Helmholz Zentrum Berlin, Berlin, Germany

9:30 - 10:00 AM Maui 316A/B

Area 9: Plenary, PV Modules & Systems Chair(s): Angele Reinders, Pierre Verlinden, Terry Jester

9:30 111

The Solar Europe Industry Initiative: Research Technology Development and Demonstration in Support of 2020 and Long-Term Targets Wim C. Sinke1,2, Daniel Fraile Montoro3 1ECN Solar Energy, Petten, Netherlands, 2European Photovoltaic Technology Platform, Brussels, Belgium, 3European Photovoltaic Industry Association, Brussels, Belgium


Break


AM Poster Session: Areas 2, 7, 8, 9, & 10



94


12:00 - 1:30 PMLunch on your own

1:30 - 3:00 PM Maui 316A/B

Area 4: Orals, Crystalline Silicon: Material and Device Characterization

Chair(s): Kentaro Kutsukake, Stefan Glunz

1:30 112

Synchrotron-Based Microanalysis of Iron Distribution After Thermal Processing and Predictive Modeling of Resulting Solar Cell Efficiency David P Fenning1, Jasmin Hofstetter2, Mariana I Bertoni1, Jean-Francois Lelievre3, Steve Hudelson4, Barry Lai5, Markus Rinio6, Carlos del Canizo2, Tonio Buonassisi1 1Laboratory for Photovoltaic Research, Massachusetts Institute of Technology, Cambridge, MA, USA, 2Instituto de Energía Solar, Universidad Politécnica de Madrid, Madrid, Spain, 3Centro Tecnológico de Silicio CENTESIL, Madrid, Spain, 41366 Technologies, North Lexington, MA, USA, 5Advanced Photon Source, Argonne National Laboratory, Argonne, IL, USA, 6Fraunhofer ISE, Laboratory and Service Center, Gelsekirchen, Germany

2:00 113

Cause of Increased Currents under Reverse-Bias Conditions of Upgraded Metallurgical Grade Multicrystalline Silicon Solar Cells Wolfram Kwapil1, Matthias Wagner2, Martin C. Schubert1, Wilhelm Warta1 1Fraunhofer Institute for Solar Energy Systems - ISE, Freiburg, Germany, 2Solar World Innovations GmbH, Freiberg, Germany

2:15 114

Iron Imaging in Multicrystalline Silicon Wafers Via Photoluminescence Yang-Chieh Fan, Jason Tan, Sieu P Phang, Daniel Macdonald The Australian National University, Canberra, ACT 0200, Australia

2:30 115

Trapping-related Recombination of Charge Carriers in Silicon Ralf Gogolin1, Nils-Peter Harder1,2, Rolf Brendel1,2,3 1Institute of Solar Energy Research Hameln (ISFH), Am Ohrberg 1, 31860 Emmerthal, Germany, 2Institute of Electronic Materials and Devices, Univ. Hanover, Schneiderberg 32, 30167 Hannover, Germany, 3Institute of Solid-State Physics, Univ. of Hanover, Appelstrasse 2, 30167 Hannover, Germany

2:45 116

Appearance of Rift Structures created by Acidic Texturizatio and their Impact on Solar Cell Efficiency Jan Nievendick, Martin Zimmer, Jonas Haunschild, Alexander Krieg, Mathias Demant, Donny George, Jochen Rentsch Fraunhofer Institute For Solar Energy Systems, Heidenhofstrasse 2, D-79110, Freiburg, Germany

WED

NES

DA

Y P

M


95


WED

NES

DA

Y P

M1:30 - 3:00 PM Ni’ihau 312

Area 1: Orals, Fundamentals & New Concepts: New PV Materials II

Chair(s): Cory Cress, Keisuke Nakayama, Takaya Kubo

1:30 117

Nanodome Solar Cells with Efficient Light Harvesting Jia Zhu1, Zongfu Yu1, Chingmei Hsu1, ikang Ding1, Michael Mcgehee1, Shanhui Fan1, Yueqin Xu2, Qi Wang2, Yi Cui1 1Stanford University, Stanford, CA, USA, 2NREL, Golden, CO, USA

2:00 118

Realization of InGaN Solar Cells on (111) Silicon Substrate Balakrishnam Jampana1, Tianming Xu2, Andrew Melton2, Muhammad Jamil2, Robert Opila1, Christiana Honsberg3, Ian Ferguson4 1Department of Material Science and Engineering, University of Delaware, Newark, DE, USA, 2School of Electrical and Computer Engineering, Georgia Institute of Technology, Atlanta, GA, USA, 3School of Electrical, Computer and Energy Engineering, Arizona State University, Tempe, AZ, USA, 4Department of Electrical and Computer Engineering, University of North Carolina-Charlotte, Charlotte, NC, USA

2:15 119

High Efficiency CdSe Quantum-Dot Sensitized Solar Cells Zhi Zheng1, Linan Zhao1, Li Wang1, Minling Liu1, Marcus S. Matthew2, Yue Liu2 1Research & Technology Lab, Honeywell Integrated Technology (China) Co. Ltd, Shanghai, China, 2Honeywell Advanced Technology Labs, Honeywell International, Inc., Minneapolis, MN, USA

2:30 120

Resonance Energy Transfer in Luminescent Solar Concentrators Rahul Bose1, Maria Gonzalez2, Phillip Jenkins3, Robert J Walters3, Andreas Büchtemann4, Clifford McLain5, Mark Moss5, John Morseman5, Pete Linsert5, Amanda J Chatten1, Keith W J Barnham1 1Imperial College London, London, United Kingdom, 2Global Strategies Group, Crofton, MD, USA, 3US Naval Research Laboratory, Washington DC, DC, USA, 4Fraunhofer Institute for Applied Polymer Research, Potsdam, Germany, 5Columbia Biosciences Corp., Columbia, MD, USA

2:45 121

Biomimetic Antireflection Coating for Efficiency Enhancement of Triple-Junction Solar Cells Utilizing Nanosphere Lithography Meng-Yih Chiu1, Feng-Yu Chang1, Chia-Hua Chang1, Min-An Tsai2, Peichen Yu1 1Institute of Electro-Optical Engineering, Hsinchu, Taiwan, 2Department of Electrophysics, Hsinchu, Taiwan

96


WED

NES

DA

Y P

M

1:30 - 3:00 PM Moloka’i 315

Area 3: Orals, III-V’s & Concentrators: Concentrator Modules and System Components

Chair(s): Kenji Araki, Andreas Bett

1:30 122

A High Concentration Photovoltaic Module Utilizing Micro-transfer Printing and Surface Mount Assembly Bruce Furman, Etienne Menard, Allen Gray, Matthew Meitl, Salvatore Bonafede, David Kneeburg, Kanchan Ghosal, Wolfgang Wagner, John Gabriel, Steven Seel, Rudolf Bukovnik, Scott Burroughs Semprius Inc, Durham, NC, USA

2:00 123

HCPV Tracker Accelerated Reliability Tests Jon G. Elerath SolFocus Inc., Mountain View, CA, USA

2:15 124

The Path to Volume Production of CPV Optics Thomas Luce Eschenbach Optik GmbH, Nuremberg, Germany

2:30 125

Micro-Optic Solar Concentration and Next-Generation Prototypes Jason H Karp, Eric J Tremblay, Joseph E Ford UC San Diego, La Jolla, CA, USA

2:45 126

Multi Receiver Concentrator Photovoltaic Testing at Extreme Concentrations Theodore G. van Kessel1, Yves Martin1, Supratik Guha1, Hussam Khonkar2, Ayman Abduljabar2, Alhassan Badahdah2, Robert Sandstrom1, Naim Moumen1, Yaseen Al-Saaedi2, Abdullah Alboiez2 1IBM, Yorktown Hts., NY, USA, 2KACST, Riyadh, Saudi Arabia


97


WED

NES

DA

Y P

M1:30 - 3:00 PM Lana’i 314

Area 6: Orals, Organic Photovoltaics: Small Molecule Based and Dye-Sensitized Solar Cells

1:30 127

Small Molecule Organic Solar Cells with Enhanced nNear-IR Photoactivity: The Role of the Oxide/Organic Interface and Nanotexturing of the Active Layers on Solar Cell Performance Neal R Armstrong, Diogenes Placencia, Erin Ratcliff, Weining Wang, P. Alex Veneman, Derek Manglesdorf University of Arizona, Tucson, AZ, USA

2:00 128

Role of Exciton Blocking Layer as Optical Spacer in CuPc/C60 Based Organic Solar Cells Debjit Datta1,2, S. Sundar Kumar Iyer2,3, Satyendra Kumar1,2 1Department of Physics, Indian Institute of Technology Kanpur, Kanpur-208016, India, 2Samtel Centre for Display Technologies (SCDT), Indian Institute of Technology Kanpur, Kanpur-208016, India, 3Department of Electrical Engineering, Indian Institute of Technology Kanpur, Kanpur-208016, India

2:15 129

Optimisation of Organic Tandem Solar Cells based on Small Molecules Moritz Riede1, Christian Uhrich2, Ronny Timmreck1, David Wynands1, Mauro Furno1, Johannes Widmer1, Gregor Schwartz2, Martin Pfeiffer2, Karl Leo1 1Institut für Angewandte Photophysik (IAPP) Technische Universität Dresden, Dresden, Germany, 2heliatek GmbH, Dresden, Germany

2:30 130

TCO-less 3D-dye Sensitized Solar Cells Consisting of Charge Separation Sheet, and Direction to High Efficiency Cells by using TCO-less Structure Shuzi Hayase1, Jun Usagawa1, Kenshiro Uzaki1, Yuhei Ogomi1, Shyam.S Pandey1, Yoshihiro Yamaguchi2, Mitsuru Kono2 1Kyushu Institute of Technology, Kitakyushu, Japan, 2Nippon Steel Cehmical Co. Ltd., Kitakyushu, Japan

2:45 131

Nanocone based Solid-state Dye-sensitized Solar Cells with Efficient Light Absorption and Carrier Collection I-Kang Ding, Jia Zhu, Yi Cui, Michael McGehee Stanford University, Stanford, CA, USA

98


WED

NES

DA

Y P

M

1:30 - 3:00 PM Kaua’i 311

Area 9: Orals, PV Modules & Systems: Integration of Grid Connected Systems

Chair(s): David Mooney

1:30 132

Solar Energy Grid Integration Systems (SEGIS): Proactive Intelligent Advances for Photovoltaic Systems Ward Bower, Scott Kuszmaul, Sig Gonzalez, Abbas Akhil Sandia National Laboratories, Albuquerque, NM, USA

2:00 133

The Levelized Cost of Energy for Distributed PV: A Parametric Study Christopher P. Cameron1, Alan C. Goodrich2 1Sandia National Laboratories, Albuquerque, NM, USA, 2National Renewable Energy Laboratory, Golden, CO, USA

2:15 134

Power Output Variability of PV System Fleets in Three Utility Service Territories in New Jersey and California Tassos Golnas, Steve Voss SunEdison, Beltsville, MD, USA

2:30 135

Estimation of Battery Capacity for Suppression of a PV Power Plant Output Fluctuation Motoki Akatsuka1, Ryoichi Hara1, Hiroyuki Kita1, Takamitsu Ito2, Yoshinobu Ueda2, Yutaka Saito3 1Hokkaido University, Sapporo, Japan, 2Meidensha Corporation, Tokyo, Japan, 3Hokkaido Electric Power Co., Inc., Ebetsu, Japan

2:45 136

Evaluating Standards and Codes Focusing on High Penetration Photovoltaic (HPPV) System Deployment Michael H. Coddington, Benjamin D. Kroposki, Thomas S. Basso National Renewable Energy Laboratory, Golden, CO, USA


99


WED

NES

DA

Y P

M1:30 - 5:00 PM Maui 316C

Joint Area 2 & 10: Panel Discussion, PV Velocity Forum: Supply and Economics in Thin-Film PV

Materials Chair(s): Tim Coutts

1:30 137

Price and Supply Rate Constraints on Te and In Based Photovoltaics Martin A. Green ARC Photovoltaics Centre of Excellence, Sydney, Australia

2:00 138

Long-term Estimates of Primary and Secondary sources of PV Materials: Recycling and Sustainability of PV Vasilis Fthenakis Brookhaven National Laboratory, Upton, NY, USA

2:30 139

Indium Market Forces Brian O’Neill AIM Specialty Materials, Cranston, RI, USA

3:00 140

Break

3:30 141

Predicting Indium and Tellurium Availability Lindsey V. Maness Geologist, Golden, CO, USA

4:00 142

Discussion on the Supply and Economics in Thin-Film PV Materials and Reception Tim Coutts Timothy J. Coutts Consulting, Evergreen, CO, USA

3:00 - 3:30 PM Exhibit Hall

Break

100


WED

NES

DA

Y P

M


PM Poster Session: Areas 1, 3, 4, & 6



7:00 - 9:00 PM Hilton Rainbow Room

Area 1 Late Night: Fundamentals & New Concepts:The Future of PV

Chair(s): Ryne Raffaelle, Nicholas (Ned) Ekins-Daukes, Yoshitaka Okada


101


TH

UR

SD

AY

PR

OG

RA

M S

UM

MA

RY


AREA LEGEND

THURSDAY PROGRAM SUMMARY

Conference Dinner6:30 - 9:30 PM

Break

8:30 PM9:00 PM

7:00 PM

8:00 PM

O4

O6

5:00 PM5:30 PM6:00 PM

P4

O1

P2

O3 O10

O9O2

1P

Break

O4

O5

Break

4:00 PM

3:00 PM3:30 PM

O2 O8

O8

1:30 PM2:00 PM

12:00 noon12:30 PM

10:00 AM10:30 AM

9:30 AM

kaerB

7O5O4O2O

Authors' Breakfast7:00 - 8:00 AMBreak8:00 AM

8:30 AM

7:00 AM

P5 O10

Exhi

bits

9:00 AM

102


TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS

THURSDAY POSTER PRESENTATIONS



Area 1: Posters, Fundamentals & New Concepts Chair(s): Ryne Raffaelle, Yoshitaka Okada, Nicholas Ekins-Daukes

Area 2: Posters, CIGS & CdTe: CIGS II Chair(s): Tokio Nakada, Jim Sites

Area 4: Posters, Crystalline Silicon: Device Fabrication and Manufacturing

Chair(s): Weiming Zhang, Stuart Bowden

Area 5: Posters, Amorphous, nc, & Film Silicon: Fundamental Material Properties and Processing

Issues Chair(s): Tobias Sontheimer, Dries van Gestel


103


TH

UR

SD

AY

AM8:30 - 10:00 AM Ni’ihau 312

Area 5: Orals, Amorphous, nc, & Film Silicon: Processing Issues for Films and Devices

Chair(s): Richard van de Sanden, Charles Teplin

8:30 143

Opportunities and Challenges of High-Rate Electron Beam Evaporation in the Preparation of Poly-Si Thin-Film Solar Cells Tobias Sontheimer1, Christiane Becker1, Bernd Rech1, Stefan Gall2, Oliver Kunz3, Renate Egan3 1Helmholtz Zentrum Berlin, Berlin, Germany, 2CSG Solar AG, Thalheim, Germany, 3CSG Solar, Botany, Australia

9:00 144

Effects of SPC temperature on properties of evaporated poly-Si thin films and solar cells Yuguo Tao1, Sergey Varlamov1, Johnson Wong1, Oliver Kunz2, Renate Egan2 1Univeristy of New South Wales, Sydney, Australia, 2CSG Solar Pty Ltd, Sydney, Australia

9:15 145

Toward Epitaxial Film-Silicon Solar Cells Grown on Display Glass David L. Young, Kirstin Alberi, Chaz Teplin, Ina Martin, Paul Stradins, Maxim Shub, Carolyn Beall, Lorenzo Roybal, Anna Duda, Eugene Iwaniczko, Manuel J. Romero, Howard M. Branz National Renewable Energy Laboratory, Golden, CO, USA

9:30 146

Application of Real Time Spectroscopic Ellipsometry for Analysis of Roll-To-Roll Fabrication of Si:H Solar Cells on Polymer Substrates Lila R Dahal, Zhiquan Huang, Dinesh Attygale, Michelle N. Sestak, Carl Salupo, Robert W Collins Center for Photovoltaics Innovation and Commercialization, The University of Toledo, Toledo, OH, USA

9:45 147

Expanding Thermal Plasma Deposited a-Si:H Thin-Films for Surface Passivation of c-Si Wafers A Illiberi, M Creatore, M.C.M. van de Sanden Eindhoven University of Technology, Eindhoven, Netherlands

104


8:30 - 10:00 AM Kaua’i 311

Area 2: Orals, CIGS & CdTe: Deposition & Characterization/Wide Band Gap & Novel Materials-

II Chair(s): David Cahen, Shigiru Niki

8:30 148

Towards Marketable Efficiency Solution-Processed Kesterite and Chalcopyrite Photovoltaic Devices David B. Mitzi1, Teodor K. Todorov1, Min Yuan1, Wei Liu1, Qing Cao1, Oki Gunawan1, Masaru Kuwahara3, Kouichi Misumi3, Andrew J. Kellock2, S. Jay Chey1, Aparna Prabhakar1, Thomas Goislard de Monsabert1, Kathleen B. Reuter1, Vaughn Deline2, Keith E. Fogel1 1IBM T. J. Watson Research Center, P.O. Box 218, Yorktown Heights, NY, USA, 2IBM Almaden Research Center, 650 Harry Rd., San Jose, CA, USA, 3Tokyo Ohka Kogyo Co., Ltd., 1590 Tabata, Samukawa-machi, Koza-gun, Kanagawa, Japan

9:00 149

The Chemical and Electronic Structure of Cu2ZnSnS4 Thin-film Solar Sell Absorbers: Surface vs. Bulk Properties Marcus Bär1, Björn Schubert1, Roberto Felix1, Björn Marsen1, Joachim Klaer1, Regan G. Wilks1, Hans-Werner Schock1, Sujitra Pookpanratana2, Monika Blum2, Stefan Krause2, Yufeng Zhang2, Clemens Heske2, Lothar Weinhardt3, Jonathan D. Denlinger4, Wanli Yang4 1Solar Energy Research, Helmholtz-Zentrum Berlin für Materialien und Energie GmbH, Berlin, Germany, 2Dept. of Chemistry, University of Nevada, Las Vegas, Las Vegas, NV, USA, 3Exp. Physik VII, Universität Würzburg, Würzburg, Germany, 4Advanced Light Source, Lawrence Berkeley National Laboratory, Berkeley, CA, USA

9:15 150

Growth-Kinetics and Thermodynamics Studies of Thin-Film Cu2ZnSnS4 for Photovoltaics Applications Glenn Teeter, Jennifer E. Leisch, Paul F. Newhouse, Matthew Young, Sally E. Asher, David S. Ginley NREL, Golden, CO, USA

9:30 151

Optimization of Composition Grading in CIGS for Flexible Solar Cells and Modules A. Chirila1, D. Guettler1, P. Bloesch1, S. Nishiwaki1, S. Seyrling1, S. Buecheler1, R. Verma1, Y. Romanyuk1, R. Ziltener2, D. Brémaud2, A.N. Tiwari1,2 1Laboratory for Thin Films and Photovoltaics, EMPA, Ueberlandstr. 129, 8600 Dueberndorf, Switzerland, 2FLISOM Ltd., Ueberlandstr. 129, 8600 Duebendorf, Switzerland

9:45 152

Cu(InGa)Se2 Photovoltaics on Insulated Stainless Steel Web Substrate Erten Eser1, Shannon Fields1, Woo K. Kim1, Elizabeth McQuiston2, William N. Shafarman1 1Institute of Energy Conversion, University of Delaware, Newark, DE, USA, 2Dow Corning Corp., Auburn, MI, USA

TH

UR

SD

AY

AM


105


TH

UR

SD

AY

AM8:30 - 10:00 AM Maui 316A/B

Area 4: Orals, Crystalline Silicon: Contacts and Device Structures

Chair(s): Joachim John, Alex Ionkin

8:30 153

Industrial LCP Selective Emitter Solar Cells with Plated Contacts Daniel Kray1, Norbert Bay1, Gisela Cimiotti1, Sven Kleinschmidt1, Nadine Kösterke1, Mark Sailer1, Armin Träger1, Holger Kühnlein1, Hartmut Nussbaumer1, Christoph Fleischmann2, Filip Granek2 1RENA GmbH, Guetenbach, Germany, 2Fraunhofer ISE, Freiburg, Germany

9:00 154

Fundamental Studies on the Front Contact Formation Resulting in a 21% Efficiency Silicon Solar Cell with Printed Rear and Front Contacts Matthias Hörteis, Jan Nekarda, Jan Benick, Stefan W. Glunz Fraunhofer ISE, Freiburg, Germany

9:15 155

20% Efficient Screen Printed LBSF Cell Fabricated using UV Laser for Rear Dielectric Removal Saptharishi Ramanathan1, Arnab Das1, Ian.B Cooper1, Ajeet Rohatgi2,3, Ingo Koehler4 1University Center of Excellence for Photovoltaics, Georgia Institute of Technology, Atlanta, GA, USA, 2Georgia Institute of Technology, Atlanta, GA, USA, 3Suniva Inc., Norcross, GA, USA, 4Merck KGAA, Darmstadt, Germany

9:30 156

High Efficiency Silicon Heterojunction Solar Cell Using Novel Structure Thomas Mueller, Stefan Schwertheim, Natalie Mueller, Katrina Meusinger, Bogsulaw Wdowiak, Oliver Grewe, Wolfgang R. Fahrner University of Hagen, Hagen, Germany

9:45 157

18.5% Laser-doped Solar Cell using a Continuous-Wave Laser on CZ P-type Silicon Adeline Sugianto, Brett Hallam, Budi Tjahjono, Ned Western, Stuart Wenham ARC Photovoltaics Centre of Excellence, UNSW, Sydney, Australia

106


TH

UR

SD

AY

AM

8:30 - 10:00 AM Moloka’i 315

Area 8: Orals, PV Characterization: Defects and Mulitjunction Device Performances

Chair(s): Daniel Abou-Ras, Manuel Romero

8:30 158

In-situ 3D X-ray Reciprocal Space Mapping During Lattice-mismatched InGaAs/GaAs Growth Takuo Sasaki, Hidetoshi Suzuki, Akihisa Sai, Yoshio Ohshita, Masafumi Yamaguchi Toyota Technological Institute, Nagoya, Japan

9:00 159

Stresses and their Relation to Defects in Multicrystalline Solar Silicon George Sarau1, Arne Bochmann1, Silke Christiansen1,2, Stephan Schönfelder3 1Institute of Photonic Technology, Jena, Germany, 2Max Planck Institute for the Science of Light, Erlangen, Germany, 3Fraunhofer Center for Silicon Photovoltaics, Halle, Germany

9:15 160

External Quantum Efficiency Measurements of Germanium Bottom Subcells: Measurement Artifacts and Correction Procedures Gerald Siefer1, Carsten Baur2, Andreas W. Bett1 1Fraunhofer ISE, Freiburg, Germany, 2European Space Agency, Noordwijk, Netherlands

9:30 161

A Capacitance Method for Analyzing Subcell Characteristics on a Multijunction Solar Cell Carmen M. Ruiz1,2, Ignacio Rey-Stolle1, Ivan Garcia1, Enrique Barrigón1, Pilar Espinet1, Carlos Algora1, Veronica Bermudez3 1Instituto de Energ´ıa Solar - Universidad Politécnica de Madrid ETSI de Telecomunicación, Avda. Complutense s/n, 28040, Madrid, Spain, 2Instituto de Ciencia de Materiales de Sevilla (ICMSE) (CSIC-Univ. Sevilla) Avda. Américo Vespucio 49 41092, Sevilla, Spain, 3Nexcis, Photovoltaic Technologies, 190, rue Celestine Coq, 13106, Rousset, France

9:45 162

Analysis of Spectral Photocurrent Response from Multijunction Solar Cells under Variable Voltage Bias Swee H. Lim, Kevin O’Brien, Elizabeth H. Steenbergen, Yong-Hang Zhang Center for Nanophotonics and School of Electrical, Computer and Energy Engineering, Arizona State University, Tempe, AZ, USA


107


TH

UR

SD

AY

AM8:30 - 10:00 AM Lana’i 314

Area 7: Orals, Space Technologies: Space Systems Chair(s): Scott Billets, Marc Breen

8:30 163

The Solar Probe Plus (SPP) Solar Array Development and Design Edward M Gaddy, Robert B Decker, Mary Kae Lockwood, Lewis M Roufberg Johns Hopkins University Applied Physics Laboratory, Laurel, MD, USA

9:00 164

IBIS (Integrated Blanket/Interconnect System), Boeing’s Solution for Implementing IMM (Inverted MetaMorphic) Solar Cells on a Light-Weight Flexible Solar Panel Marc L. Breen, Andrew R. Street, Darren S. Cokin, Ray Stribling, Anne V. Mason, Sam C. Sutton Boeing Company, El Segundo, CA, USA

9:15 165

Progress in Development of Ultra-Lightweight Solar Panel Using Space Solar Sheet Kazunori Shimazaki1, Yuki Kobayashi1, Masato Takahashi1, Mitsuru Imaizumi1, Tatsuya Takamoto2, Takehiko Ito3, Yukishige Nozaki3 1Japan Aerospace Exploration Agency (JAXA), Tsukuba, Japan, 2SHARP Corporation, Yamatokoriyama, Japan, 3NEC TOSHIBA Space Systems, Ltd., Fuchu, Japan

9:30 166

A Case Study: Integrating Triple-Junction Solar Cells Into Flat-Folding Flexible Solar Array Panels John L. Gibb, Scott A. Billets Lockheed Martin Space Systems Co., Sunnyvale, CA, USA


Break

108


TH

UR

SD

AY

AM

10:30 - 1:00 PM Maui 316C

Area 10: Gigawatt Scale Manufacturing Chair(s): Kaitlyn vanSant, Leon Fabick

10:30 167

PV Manufacturing Scaling to Giga-Watt Capacity: Lessons Learned from the Semiconductor and Flat Panel Display Industry David Krick1, Helfried Weinzerl2, Terry Behrens3 1CH2M Hill, Pittsburgh, PA, USA, 2CH2M Hill, Santa Ana, CA, USA, 3CH2M Hill, Portland, OR, USA

11:00 168

Perspective from Equipment Supply: Scaling to GW-size Factories Chris O’Brien Oerlikon Solar

11:30 169

Towards a Sustainable PV Industry Lisa Krueger, Jolanka Fisher, Amy Meader First Solar, Inc., Tempe, AZ, USA

11:45 170

Life-Cycle Assessment of Organic Solar Cell Technologies Annick Anctil1,2, Callie W. Babbitt1, Brian J. Landi2,3, Ryne P. Raffaelle4 1Golisano Institute for Sustainability, Rochester, NY, USA, 2NanoPower Research Labs, Rochester, NY, USA, 3Chemical & Biomedical Engineering, Rochester, NY, USA, 4National Renewable Energy Lab (NREL), Golden, CO, USA

12:00 Break

12:15 172

A Post Scripts to GW Scale Manufacturing:Is Commercialization of Large Scale Photovoltaics Tougher than the Iron Man Triathlon? Roger G Little Spire Corporation, Bedford, MA, USA


AM Poster Session: Areas 1, 2, 4, & 5

SEE PAGE 191-204 FOR POSTER PRESENTATION LISTINGS.

12:00 - 1:30 PM

Lunch on your own


109


TH

UR

SD

AY

PM1:30 - 3:00 PM Ni’ihau 312

Area 5: Orals, Amorphous, nc, & Film Silicon: Novel Concepts for Solar Cell Devices

Chair(s): Makoto Konagai, Vikram Dalal

1:30 173

a-Si Solar Cells with Embedded Silver Nanoparticles Renrong Liang, Rudi Santbergen, Miro Zeman Delft University of Technology, Delft, Netherlands

2:00 174

Light Scattering at Nano-Textured Surfaces in Thin Film Silicon Solar Cells Franz-Josef Haug1, Corsin Battaglia1, Didier Dominé2, Christophe Ballif1 1École Polytechnique Fédérale de Lausanne (EPFL), Insitute of Microengineering (IMT), Photovoltaics and Thin Film Electronics Laboratory, Neuchâtel, Switzerland, 2University of Applied Sciences and Arts of Southern Switzerland (SUPSI), Institute for Applied Sustainability to the Built Environment (ISAAC), Canobbio, Switzerland

2:15 175

Plasmonic Light Trapping for Thin Film Silicon Solar Cells Vivian E. Ferry1,2, Marc A. Verschuuren3, Hongbo B. T. Li4, Ruud E. I. Schropp4, Harry A. Atwater2, Albert Polman1 1FOM Institute - AMOLF, Amsterdam, Netherlands, 2California Institute of Technology, Pasadena, CA, USA, 3Philips Research, Eindhoven, Netherlands, 4Utrecht University, Utrecht, Netherlands

2:30 176

High Open-Circuit Voltage Oxygen-Containing Si Quantum Dots Superlattice Solar Cells Shigeru Yamada1, Yasuyoshi Kurokawa1, Shinsuke Miyajima1, Akira Yamada1,2, Makoto Konagai1,2 1Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan, 2Photovoltaics Research Center (PVREC), Tokyo Institute of Technology, Tokyo, Japan

2:45 177

Amorphous Silicon Nanodome Solar Cells with Efficient Photon Management Jia Zhu1, Ching-Mei Hsu1, Zongfu Yu1, Yueqin Xu2, Qi Wang2, Shanhui Fan1, Yi Cui1 1Stanford University, Stanford, CA, USA, 2National Renewable Energy Laboratory, Golden, CO, USA

110


TH

UR

SD

AY

PM

1:30 - 3:00 PM Kaua’i 311

Area 2: Orals, CIGS & CdTe: Advanced Processes: Atmospheric and Vacuum

Chair(s): Robert Birkmire, Immo Koetschau

1:30 178

Commercial-scale Sources for the Evaporation of Elemental Cu, Ga, and In: Modeling, Design, and Validation Gregory M. Hanket, Robert W. Birkmire, Shannon Fields, Erten Eser Institute of Energy Conversion, University of Delaware, Newark, DE, USA

1:45 179

Linear Source Technology Review for CIGS Co-Evaporation on Glass and Flexible Substrates Kenneth Pfeiffer1, Chad Conroy2, Jian-gang Weng2, Doug Brown1, Ramya Chandrasekaran1, David Fobare3, David Metacarpa3, John Patrin2 1Veeco Solar Equipment, Lowell, MA, USA, 2Veeco Instruments, St. Paul, MN, USA, 3Veeco Solar Process Development Center, Clifton Park, NY, USA

2:00 180

Continuous In-Line Processing of CdS/CdTe Devices: Process Control Using XRF and Efficient Heating Pavel S. Kobyakov1, Nathan Schuh1,2, Kevin Walters1, Venkatesan Manivannan1, W. S. Sampath1 1Materials Engineering Lab, Colorado State University, Fort Collins, CO, USA, 2Abound Solar, Loveland, CO, USA

2:15 181

CIGS Thin Films Prepared by Sputtering and Selenization by using In2Se3, Ga2Se3 and Cu as Sputtering Targets. Nicola Romeo1, Alessio Bosio1, Samantha Mazzamuto1, Daniele Menossi1, Alessandro Romeo2 1University of Parma, Parma, Italy, 2University of Verona, Verona, Italy

2:30 182

Thin Specialty Glass for Reliable Thin Film PV Modules James E Webb1, David I Wilcox1, Kevin L Wasson1, Suresh T Gulati1, Girma Bitsuamlak2 1Corning Incorporated, Corning, NY, USA, 2Florida International University, Miami, FL, USA

2:45 183

Electrodeposition of Cu-In-Ga films for the Preparation of CIGS Solar Cells Serdar Aksu, Mustafa Pinarbasi SoloPower, Inc., San Jose, CA, USA


111


TH

UR

SD

AY

PM1:30 - 3:00 PM Maui 316A/B

Area 4: Orals, Crystalline Silicon: Feedstock and Crystallization

Chair(s): Armin Aberle, Homer Antoniadis

1:30 184

Multicrystalline Solar Grade Silicon Solar Cells Kristian Peter1, Radovan Kopecek1, Erik Enebakk2, Anne-K. Soiland2, Svein Grandum2 1ISC Konstanz, Konstanz, Germany, 2Elkem Solar, Kristiansand, Norway

2:00 185

Impact of Metal Contamination in Silicon Solar Cell Gianluca Coletti, Paula C. Bronsveld Energy Research Center of the Netherlands, Petten, Netherlands

2:15 186

Formation Mechanism of Twin Boundaries in Silicon Multicrystals During Crystal Growth Kentaro Kutsukake, Takuro Abe, Noritaka Usami, Kazuo Nakajima Tohoku University, Sendai, Japan

2:30 187

Quality Control using Luminescence Imaging in Production of mc- Solar Cells from UMG Feedstock Jonas Haunschild, Markus Glatthaar, Stephan Riepe, Stefan Rein Fraunhofer Institute for Solar Energy Systems, Freiburg, Germany

2:45 188

High Efficiency Solar Cells using Small Size Ingots with 30 cmφ by Controlling the Distribution and Orientation of Dendrite Crystals Grown along the Bottom of the Ingots Kazuo Nakajima1, Kentaro Kutsukake1, Kozo Fujiwara1, Usami Usami1, Satoshi Ono2, Yamasaki Yamasaki3 1IMR, Tohoku University, Sendai, Japan, 2Dai-Ichi Kiden Corporation, Chofu, Japan, 3Sharp Corporation, Katsuragi-shi, Japan

112


1:30 - 3:00 PM Moloka’i 315

Area 3: Orals, III-V’s & Concentrators: High and Low Concentration PV Systems and Plants

Chair(s): Scott Burroughs, Pierre Verlinden

1:30 189

Amonix CPV Solar Power Plants Geoffrey S Kinsey, Kenneth Stone, Joseph Brown, Vahan Garboushian Amonix, Inc., Torrance, CA, USA

2:00 190

Simulation and Characterization of High Efficiency Back Contact Solar Cells for Low Concentration Photovoltaics Marius M Bunea, Keith Johnston, Chris M. Bonner, Peter Cousins, David D. Smith, Doug H. Rose, William P. Mulligan, Richard M. Swanson SunPower Corp., San Jose, CA, USA

2:15 191

The Validation and Verification of CFD Models of Heat Transfer and Airflow within CPV Modules Deborah A Adkins The University of Nottingham, Nottingham, United Kingdom

2:30 192

Develop and Optimization of a Low Concentration PV/T System Alberto Reatti1, Leonardo Serri2, Marian kazimierczuk3, Mattia Beltramini2 1Department of Electronics and Telecommunications, Università degli Studi di Firenze, Firenze, Italy, 2Department of Energetics, Università degli Studi di Firenze, Firenze, Italy, 3Department of Electrical Engineering Wright State University, Firenze, OH, USA

2:45 193

A 20-Sun Hybrid PV/Thermal Linear Microconcentrator System for Urban Rooftop Applications Daniel C Walter, Vernie A Everett, Andrew W Blakers, Marta Vivar, Judy R Harvey, Ruud Van Scheppingen, Sachin R Surve, Jelena Muric-Nesic Australian National University, Canberra, Australia

TH

UR

SD

AY

PM


113


TH

UR

SD

AY

PM1:30 - 3:00 PM Lana’i 314

Area 8: Orals, PV Characterization: Recombination Rate and Trap Measurements

Chair(s): Angus Rockett, Gerald Siefer

1:30 194

Efforts to Develop Excess-Carrier Recombination Lifetime Measurement Standards for Silicon PV Ron Sinton Sinton Instruments Inc, Boulder, CO, USA

2:00 195

Transmission Modulated Photoconductive Decay: A New Lifetime Diagnostic System For Photovoltaic Materials Richard K Ahrenkiel Colorado School of Mines, Golden, CO, USA

2:15 196

Simultaneous Determination of Carrier Lifetime and Net Dopant Concentration of Silicon Wafers from Photoluminescence Johannes A. Giesecke, Dominic Walter, Fabian Kopp, Philipp Rosenits, Martin C. Schubert, Wilhelm Warta Fraunhofer Institute for Solar Energy Systems, Freiburg, Germany

2:30 197

Next Generation Inline Minority Carrier Lifetime Metrology on Multicrystalline Silicon Bricks for PV N Schüler1, D Mittelstrass1, K Dornich1, J R Niklas1, H Neuhaus2 1Freiberg Instruments GmbH, Am St. Niclas Schacht 13, Freiberg, Germany, 2Solar World Innovations GmbH, Berthelsdorfer Str. 111A, Freiberg, Germany

2:45 198

Study of Si-SiNx Interface Properties on Flat and Textured Surfaces by Deep-level Transient Spectroscopy Chun Gong1,2, Eddy Simoen1, Lu Zhao1,2, Niels E. Posthuma1, Emmanuel Van Kerschaver1,3, Jef Poortmans1,2, Robert Mertens1,2 1IMEC, Leuven, Belgium, 2Katholieke Universiteit Leuven, Leuven, Belgium, 3Solexel, Inc,, Milpitas, CA, USA

3:00 - 3:30 PM Ala Halawai Concourse

Break

114


1:30 - 5:00 PM Maui 316C

Area 10: Panel Discussion, PV Velocity Forum: Women in PV

Chair(s): Veronica Bermudez

1:30 199

Introduction Veronica Bermudez

2:15 200

Retrospective of women careers in energy in the last 30 years Martha Duggan UniSolar

2:40 201

Differences observed by women in the business vs. scientific communities, how teams can really make or break a company and how women play a role in the team Martha Symko-Davies NREL

2:50 202

Women in Science and Engineering: Introduction and Focus in PV Sheila Bailey NASA Glenn Research Center

3:05 203

BREAK

3:35 204

What is Your Value Proposition? Iga Hallberg HelioVolt Corporation

3:50 205

The feminine balance to the technical perspective Christy Herig Solar Electric Power Association

4:15 206

I’m Gonna be an Engineer Larry Kazmerski NREL

4:40 207

Open discussions and closing

TH

UR

SD

AY

PM


115


TH

UR

SD

AY

PM3:30 - 5:00 PM Kaua’i 311

Area 2: Orals, CIGS & CdTe: Deposition & Characterization/Wide Band Gap & Novel

Materials-III Chair(s): Rob Collins, Glenn Teeter

3:30 208

Critical Issues for High-Efficiency Low-Cost CIGS Solar Cells and Modules S. Niki1, S. Ishizuka1, H. Komaki1, Y. Kamikawa-Shimizu1, S. Furue1, S.W. Choi1, K. Matsubara1, H. Shibata1, A. Yamada1, H. Nakanishi2, N. Terada3, T. Sakurai4, K. Akimoto4 1Research Center for Photovoltaics, AIST, Tsukuba, Japan, 2Tokyo University of Science, Chiba, Japan, 3Kagoshima University, Kagoshima, Japan, 4Tsukuba University, Tsukuba, Japan

4:00 209

In-situ Study of CIGS Dielectric Functions Evolution as a Function of Copper Content Sylvain Marsillac, Vikash Ranjan, Scott Little University of Toledo, Toledo, OH, USA

4:15 210

P- to N-type Conversion with Sodium Addition in Bridgman-grown CuInSe2 Hadley F Myers, Clifford H Champness, Ishiang Shih McGill University, Montreal, QC, Canada

4:30 211

Effects of As-Deposited CdTe Microstructure on Solar Cell Performance Michelle N. Sestak, Jian Li, Jie Chen, Bradford J. Smith, Abbasali Naseem, Prakash Koirala, Meghan R. Mapes, Robert W. Collins Center for Photovoltaics Innovation and Commercialization, The University of Toledo, Toledo, OH, USA

4:45 212

Local Charge Neutrality Condition, Fermi Level, and Majority Carrier Density of Semiconductors with Impurity/Defect States of Multiple Energy Levels and of Multiple Atomic Configurations Ken K. Chin1, Suhuai Wei2 1Dept. of Physics and Apollo CdTe Solar Energy Research Center, NJIT, Newark, NJ, USA, 2National Renewable Energy Laboratory, Golden, CO, USA

116


TH

UR

SD

AY

PM

3:30 - 5:00 PM Maui 316A/B

Area 4: Orals, Crystalline Silicon: Surface Passivation

Chair(s): Daniel Biro, Keith McIntosh

3:30 213

Silicon Surface Passivation by Ultrathin Al2O3 Films and Al2O3/SiNx Stacks Jan Schmidt, Boris Veith, Florian Werner, Dimitri Zielke, Rolf Brendel Institute for Solar Energy Research Hamelin (ISFH), Emmerthal, Germany

4:00 214

Changes in the Al2O3/Si Interface Properties due to a Post-deposition Anneal Jan Benick1, Armin Richter1, Tsu-Tsung A. Li3, Nicholas Grant2, Keith R. McIntosh2, Yongling Ren2, Klaus J. Weber2, Martin Hermle1, Stefan W. Glunz1 1Fraunhofer ISE, Freiburg, Germany, 2Centre for Sustainable Energy Systems, The Australian National University, Canberra, Australia, 3School of Engineering, The Australian National University, Canberra, Australia

4:15 215

Charge Stability in LPCVD Silicon Nitride for Surface Passivation of Silicon Solar Cells Yongling Ren, Klaus J Weber, Da Wang, Natalita Maulani Nursam Centre for Sustainable Energy Systems, College of Engineering and Computer Science, The Australian National University, Canberra, Australia

4:30 216

Advanced Approach for Surface Decoupling in Crystalline Silicon Solar Cells Victor Prajapati1,2, Joachim John1, Jef Poortmans1,2, Robert Mertens1,2 1IMEC, Leuven, Belgium, 2Katholieke Universiteit Leuven, Leuven, Belgium

4:45 217

Practical Challenges of Achieving High Efficiency Boron Back Surface Field Solar Cells A Das, S Ramanathan, A Upadhyaya, A Rohatgi University Center of Excellence for Photovoltaics, Georgia Institute of Technology, Atlanta, GA, USA


117


TH

UR

SD

AY

PM3:30 - 5:00 PM Ni’ihau 312

Area 1: Orals, Fundamentals & New Concepts: Nanowire Solar Cells

Chair(s): Cory Cress, Takashi Kita, Francesca Ferrazza

3:30 218

Wire Textured Silicon Solar Cells Kejia Albert Wang1, Oki Gunawan1, Naim Moumen1, George Tulevski1, Hisham Mohamed2, Babak Fallah3, Emanuel Tutuc3, Supratik Guha1 1IBM T.J. Watson Research Center, Yorktown Heights, NY, USA, 2Egypt-IBM Nanotechnology Research Center Labs, Yorktown Heights, NY, USA, 3Department of Electrical and Computer Engineering, University of Texas Austin, Austin, TX, USA

4:00 219

GaP/Si Wire Array Solar Cells Adele C Tamboli, Daniel B Turner-Evans, Manav Malhotra, Michael D Kelzenberg, Harry A Atwater California Institute of Technology, Pasadena, CA, USA

4:15 220

A Study of Lateral Collection Single Junction a-Si:H Solar Cell Devices Using Nano-scale Columnar Array Structures Wook Jun Nam1, Stephen Fonash1, Ting Liu2, Sigurd Wagner2 1Solarity LLC, State College, PA, USA, 2Department of Electrical Engineering & PRISM, Princeton University, Princeton, NJ, USA

4:30 221

Quantum Posts for Intermediate Band Solar Cells D. Alonso-Álvarez1, B. Alén1, J. M. Ripalda1, A. G. Taboada1, J. M. Llorens1, A. Rivera1, Y. González1, L. González1, F. Briones1, E. Antolín2, A. Martí2, A. Luque2, J. Hernández3, M. Herrera3, S. I. Molina3 1Instituto de Microelectrónica de Madrid, CNM (CSIC), Tres Cantos, Spain, 2Instituto de Energía Solar, IES-UPM, Madrid, Spain, 3Departamento de Ciencia de los Materiales e Ing. Metalúrgica y Q. I. Universidad de Cádiz, Puerto Real, Spain

4:45 222

Improving Absorption in Thin Silicon Nanowire Photovoltaics Erik C Garnett, Criag Peters, Mark Brongersma, Yi Cui, Mike McGehee Stanford University, Department of Materials Science, Stanford, CA, USA

118


TH

UR

SD

AY

PM

3:30 - 5:00 PM Lana’i 314

Area 6: Orals, Organic Photovoltaics: Hybrid and Advanced Concept Organic Solar Cells

3:30 223

Plasmonic-Enhanced Polymer Photovoltaic Devices Incorporating Au Nanoparticles Jyh-Lih Wu1, Chia-Ling Lee2, Fang-Chung Chen2, Chun-Hong Kuo3, Michael H. Huang3 1Department of Photonic & Institute of Electro-Optical Engineering, National Chiao Tung University, Hsinchu, Taiwan, 2Department of Photonic & Display Institute, National Chiao Tung University, Hsinchu, Taiwan, 3Department of Chemistry, National Tsing Hua University, Hsinchu, Taiwan

3:45 224

Hybrid Solar Cells using GaAs Nanopillars Ramesh Babu Laghumavarapu1, Giacomo Mariayani1, Joshua Shapiro1, Bertrand de Villers2, Pradeep Senanayake1, Andrew Lin1, Benjamin Schwartz2, Diana L Huffaker1 1Electrical Engineering Department, University of California Los Angeles, Los Angeles, CA, USA, 2Department of Chemistry, University of California Los Angeles, Los Angeles, CA, USA

4:00 225

GaAs Nanowire/PEDOT:PSS Hybrid Solar Cells: Morphological and Performance Characterization Jiun-Jie Chao, Shu-Chia Shiu, Ching-Fuh Lin National Taiwan University, Taipei, Taiwan

4:15 226

Effect of Nanowire Lengths on Polymer-Si Nanowire Hybrid Solar Cells Dai-Hong Lin, Shu-Chia Shiu, Jing-Shun Huang, Ching-Fuh Lin National Taiwan University, Taipei, Taiwan

4:30 227

Phosphonate Self-Assembled Monolayers as Organic Linkers in Solid-State Quantum Dot Sensitized Solar Cells Pendar Ardalan, Thomas P. Brennan, Jonathan R. Bakke, Stacey F. Bent Stanford University, Stanford, CA, USA

4:45 228

New Architectural Device Design to Optimize the Material Needs of Organic PV Cells Seamus A Curran, James Dewald University of Houston, Houston, TX, USA


119


TH

UR

SD

AY

PM3:30 - 5:00 PM Moloka’i 315

Area 9: Orals, PV Modules & Systems: Improving Performance of PV systems

Chair(s): Greg Ball, Alain Garnier

3:30 229

Compressed-Air Energy Storage Systems for Stand-Alone Off-Grid Photovoltaic Modules Krishna Muralidharan1, Dominique VIllela1, Scott De Valle1, Mark Alvarez2, Pierre Deymier1, George Frantziskonis1 1Materials Science and Engineering, University of Arizona, Tucson, AZ, USA, 2Civil Engineering and Engineering Mechanics, University of Arizona, Tucson, AZ, USA

4:00 230

Dynamic Power Optimization of Contoured Flexible PV Array Under Non-Uniform Illumination Conditions Pooja Sharma, Bhawani Patnaik, Siddhartha.P Duttagupta, Vivek Agarwal Department of Electrical Engineering, IIT Bombay, Mumbai, India

4:15 231

Measuring and Modeling the Effect of Snow on Photovoltaic System Performance Loren Powers, Tim Townsend, Jeff Newmiller BEW Engineering, San Ramon, CA, USA

4:30 232

Light Management for Reduction of Busbar- and Gridline Shadowing in Photovoltaic Modules Joachim J Jaus1, Henrikki Pantsar2, Matthias Duell1, Hans Herfurth2, Daniel Doble1 1Fraunhofer Center for Sustainable Energy Systems, Cambridge, MA, USA, 2Fraunhofer Center for Laser Technology, Plymouth, MI, USA

4:45 233

Temperature Testing and Analysis of PV Modules Per UL 1703 and IEC 61730 Standards Jaewon Oh1, GovindaSamy TamizhMani1,2 1Arizona State University, Mesa, AZ, USA, 2TÜV Rheinland PTL, Tempe, AZ, USA

6:30 - 9:30 PM ‘Iolani Palace

Conference Dinner

120


FR

IDA

Y P

RO

GR

AM

SU

MM

AR

Y


AREA LEGEND

FRIDAY PROGRAM SUMMARY

8:30 PM9:00 PM

7:00 PM

8:00 PM

5:00 PM5:30 PM6:00 PM

4:00 PM

3:00 PM3:30 PM

O5

1:30 PM2:00 PM

12:00 noon12:30 PM

10:00 AM10:30 AM

9:30 AM

kaerB

4OO2O1

Authors' Breakfast7:00 - 8:00 AMBreak

O7O6 O9

8:00 AM8:30 AM

7:00 AM

O3O1

Closing Session

O2 O4 O8

9:00 AM


121


FR

IDA

Y A

M8:30 - 10:00 AM Kaua’i 311

Area 2: Orals, CIGS & CdTe: Transparent Conductors, Buffers, and Contacts

Chair(s): Kannan Ramanathan, Dean Levi

8:30 234

Amorphous Transparent Conductors for PV Applications J.D. Perkins1, T. Gennett1, J.E. Leisch1, R. Sundaramoorthy1, I.L. Repins1, M.F.A.M. van Hest1, M.I. Bertoni2, K.R. Poepelmeier2, T.O. Mason2, D.S. Ginley1 1National Renewable Energy Lab, Golden, CO, USA, 2Northwestern University, Evanston, IL, USA

8:45 235

Highly Improved Transparent Conductors By Combination Of TCOs And Metallic Grids Joop van Deelen, Henk Rendering, Hero het Mannetje, Bert Huis in ‘t Veld, Mirjam Theelen, Zeger Vroon, Paul Poodt, Arjan Hovestad TNO Science and Industry, Eindhoven, Netherlands

9:00 236

The Application of ZnO1-xSx as a Buffer Layer in CdTe Solar Cells Julian Perrenoud1, Stephan Buecheler1, Lukas Kranz1, Jarmo Skarp2, Ayodhya Tiwari1 1EMPA, Duebendorf, Switzerland, 2Beneq, Vantaa, Finland

9:15 237

Effects of Back Contacting Method and Temperature on CdTe/CdS Solar Cells Joel N. Duenow, Ramesh G. Dhere, Jian Li, Matthew R. Young, Timothy A. Gessert National Renewable Energy Laboratory, Golden, CO, USA

9:30 238

Reaction Pathways and Kinetics of MoSe2 Rangarajan Krishnan, Timothy James Anderson University of Florida, Gainesville, FL, USA

9:45 239

Effects of Cu and CdCl2 Treatment on the Stability of Sputtered CdS/CdTe Solar Cells Naba R. Paudel, Kristopher A. Wieland, Alvin D. Compaan University of Toledo, Toledo, OH, USA

122


FR

IDA

Y A

M

8:30 - 10:00 AM Maui 316A/B

Area 4: Orals, Crystalline Silicon: Devices and Fabrication II

Chair(s): Allen Barnett, Kay Cesar

8:30 240

Pilot Line Processing of 18.6% Efficient Rear Surface Passivated Large Area Solar Cells Andreas Wolf1, Edgar A. Wotke1, Sebastian Mack1, Bernd Bitnar2, Christian Koch2, Ralf Preu1, Daniel Biro1 1Fraunhofer Institute for Solar Energy Systems ISE, Freiburg, Germany, 2SolarWorld Innovations GmbH, Freiberg, Germany

9:00 241

Improving Performance of Solar Cell by Full Aluminum Back Surface Field Tung Pham, Weiming Zhang 1, W. Conshohocken, PA, USA

9:15 242

Large Area Industrial Solar Cells on Low-Cost 100% MC SOG Si Substrates: Efficiencies Exceeding 16% Andreas Halm1, Johann Jourdan1, Scott Nichol2, Birgit Ryningen3, Harsharn Tathgar3, Radovan Kopecek1 1 ISC Konstanz, Konstanz, Germany, 26N Silicon Inc., Vaughan, ON, Canada, 3Umoe Solar AS, Lysaker, Norway

9:30 243

In Line and Vertical Texturing of Mono Crystaline Silicon Solar Cells Matthew Moynihan1, Bob Barr1, Corey O’Connor1, Scott Tiffany1, George Allardyce1, Wolfgang Braun1, Katrin Birmann2, Jochen Rentsch2 1Dow Chemical Company, Marlboro, MA, USA, 2Fraunhofer ISE, Freiburg, Germany

9:45 244

Decoupling Charge Carrier Collection and Metallization Geometry of Back-contacted Back-junction Silicon Solar Cells by using Insulating Thin Films Christian Reichel, Markus Reusch, Filip Granek, Martin Hermle, Stefan W. Glunz Fraunhofer Institute for Solar Energy Systems, Freiburg, Germany


123


FR

IDA

Y A

M8:30 - 10:00 AM Ni’ihau 312

Area 1: Orals, Fundamentals & New Concepts: New PV Materials I

Chair(s): Charlie Lieber, Jamie Phillips, Masakazu Sugiyama

8:30 245

Optimized Mg Doping in Zn3P2 Homojunction Solar Cells Gregory M. Kimball, Yunbin Guan, Nathan S. Lewis, Harry A. Atwater California Institute of Technology, Pasadena, CA, USA

9:00 246

Progress on III-Nitride/Silicon Hybrid Multijunction Solar Cells Lothar A. Reichertz1,2, Iulian Gherasoiu1, Kin Man Yu2, Joel W. Ager III2, Vincent M. Kao2, Wladek Walukiewicz1,2 1RoseStreet Labs Energy, Phoenix, AZ, USA, 2Lawrence Berkeley National Laboratory, Materials Sciences Division, Berkeley, CA, USA

9:15 247

Novel, Single-Crystalline-Like Templates on Low-Cost, Flexible Substrates for High Efficiency Photovoltaics Venkat Selvamanickam1, Senthil Sambandam2, Aarthi Sundaram1, Seunghee Lee1, Andrei Rar2, Xuming Xiong2, Gang Shi1, Cao Jian1, Alex Freundlich1 1University of Houston, Houston, TX, USA, 2SuperPower Inc., Schenectady, NY, USA

9:30 248

Novel Transparent Conducting Barriers for Photovoltaics Lin J Simpson, Arrelaine Dameron, Steven Christensen, Thomas Gennett, Matthew Reese, Joseph Berry, John Perkins, Dave Ginley National Renewable Energy Laboratory, Golden, CO, USA

9:45 249

Optical Meta-Structures for Trapping Light in Thin Si Solar Cells Vasundara V Varadan, Liming Ji, Matthew G Young University of Arkansas, Fayetteville, AR, USA

124


FR

IDA

Y A

M

8:30 - 10:00 AM Lana’i 314

Area 6: Orals, Organic Photovoltaics: Stability, Processing and Packaging of Organic Solar Cells

8:30 250

Enhanced Lifetime in Unencapsulated Organic Photovoltaics with Air Stable Electrodes Matthew T. Lloyd, Dana C. Oslon, Joseph J. Berry, Nikos Kopidakis, Matthew O. Reese, K. Xerxes Steirer, David S. Ginley National Renewable Energy Laboratory, Golden, CO, USA

9:00 251

Large Area Modules Based on Low Band-gap Polymers Eva Bundgaard, Frederik Krebs Risø DTU, Roskilde, Denmark

9:15 252

Efficient Polymer Solar Cells via an All-Spray-Coated Deposition Claudio Girotto1,2, Davide Moia3, Barry P. Rand1, Tom Aernouts1, Jan Genoe1, Paul Heremans1,2 1IMEC, Leuven, Belgium, 2Katholieke Universiteit Leuven, Leuven, Belgium, 3Politecnico di Milano, Milano, Italy

9:30 253

Highly-stable and Efficient Polymer Solar Cells Incorporating Nanoscale Buffer Layers Induced by Spontaneous Vertical Phase Separation Shang-Chieh Chien, Hau-Chih Yang, Fang-Chung Chen Department of Photonics & Institute of Electro-optical Engineering, National Chiao Tung University, HsinChu City, Taiwan


125


FR

IDA

Y A

M8:30 - 10:00 AM Moloka’i 315

Area 9: Orals, PV Modules & Systems: Predictive Performance Modeling

Chair(s): Katie Brown, Angele Reinders

8:30 255

A Standardized Approach to PV System Performance Model Validation Joshua S Stein1, Christopher P. Cameron1, Ben Bourne2, Adrianne Kimber3, Jean P. Posbic4, Terry Jester5 1Sandia National Laboratories, Albuquerque, NM, USA, 2SunPower Corporation, Richmond, CA, USA, 3First Solar, Oakland, CA, USA, 4BP Solar, Fredrick, MD, USA, 5Hudson Clean Energy Partners, Teaneck, NJ, USA

9:00 256

Assessing Technical Potential for City PV Deployment Using NREL’s “In My Backyard” Tool Kate H. Anderson, Michael H. Coddington, Benjamin D. Kroposki National Renewable Energy Laboratory, Golden, CO, USA

9:15 257

Impact of Microclimates on Solar Resource: Case Study of the Solar Resource in San Francisco over the last 10 years. Lori Mitchell, James Andrews, Jamie Seidel, Randal Smith SFPUC, San Francisco, CA, USA

9:30 258

Evaluation of Solar Irradiance Predictive Models Christoper P. Cameron, David L, King, Joshua S. Stein, Daniel M. Riley Sandia National Laboratories, Albuquerque, NM, USA

9:45 259

Rating of Annual Energy Yield More Sensitive to Reference Power than Module Technology Bastian Zinsser1, George Makrides2, Markus B. Schubert1, George E. Georghiou2, Juergen H. Werner1 1Universität Stuttgart, Institut für Physikalische Elektronik, Stuttgart, Germany, 2University of Cyprus, Department of Electrical and Computer Engineering, Nicosia, Cyprus

126


FR

IDA

Y A

M

8:30 - 10:00 AM Maui 316C

Area 7: Orals, Space Technologies: Flight Performance and Environmental Effects

Chair(s): Bao Hoang, Simon Liu

8:30 260

Modeling of the Degradation of III-V Triple-junction Cells due to Particle Irradiation on the Basis of Component Cells Carsten Baur European Space Agency, Noordwijk, Netherlands

8:45 261

SCREAM: A New Code for Solar Cell Degradation Prediction Using the Displacement Damage Dose Approach Scott R. Messenger, Eric Jackson, Jeffrey H. Warner, Robert J. Walters US Naval Research Laboratory, Washington, DC, USA

9:00 262

Durability Evaluation of InGaP/GaAs/Ge Triple-Junction Solar Cells in High-Intensity and High-Temperature Environments for Mercury Exploration Mission Takanobu Shimada1, Hiroyuki Toyota1, Akio Kukita1, Mitsuru Imaizumi2, Kazuyuki Hirose1, Michio Tajima1, Hiroyuki Ogawa1, Hajime Hayakawa1, Akira Okamoto3, Yukisige Nozaki4, Hirokazu Watabe4, Tadashi Hisamatsu5 1Institute of Space and Astronautical Science, JAXA, Sagamihara, Japan, 2Aerospace Research and Development Directorate, JAXA, Tsukuba, Japan, 3NEC Corporation, Fuchu, Japan, 4NEC TOSHIBA Space Systems, Ltd., Fuchu, Japan, 5SHARP Corporation, Yamatokoriyama, Japan

9:15 263

Electrostatic Discharge Test with Simulated Coverglass Flashover for Multi-junction GaAs/Ge Solar Array Design Bao Hoang1, Frankie Wong1, Victor Funderburk1, Mengu Cho2, Kazuhiro Toyoda2, Hirokazu Masui2 1Space Systems Loral, Palo Alto, CA, USA, 2Kyushu Institute of Technology, Kitakyushu, Japan

9:30 264

Initial Results from the Second Forward Technology Solar Cell Experiment Phillip P. Jenkins1, Robert J. Walters1, Maria Gonzales2, Justin Lorentzen1, Joseph M. Flatico3, Lawrence C. Greer4, Michael J. Krasowski4 1Naval Research Lab, Washington, DC, USA, 2Global Strategies Group, Crofton, MD, USA, 3Ohio Aerospace Institute, Brook Park, OH, USA, 4NASA Glenn Research Center, Brook Park, OH, USA

9:45 265

Performance of the First Flight Experiment with Dedicated Space CIGS Cells onboard the Delfi-C3 Nanosatellite Tomas Jansen1, Angèle Reinders1, Gijs Oomen2, Jasper Bouwmeester3 1Department of Design, Production and Management, University of Twente, Enschede, Netherlands, 2Department of Operations & Engineering, Dutch Space, Leiden, Netherlands, 3Chair of Space Systems Engineering, Faculty of Aerospace Engineering, Delft University of Technology, Delft, Netherlands


127


FR

IDA

Y A

M10:00 - 10:30 AM Ala Halawai Concourse

Break

10:30 - 12:00 PM Moloka’i 315

Area 5: Orals, Amorphous, nc, & Film Silicon: Devices and Modules

Chair(s): Takuya Matsui, Cy Herring

10:30 266

Fabrication Technology for Thin Film Silicon Hybrid Solar Cells and Modules Toshiaki Sasaki, Naoki Kadota, Susumu Fukuda, Akihiko Hakajima, Takuji Nomura Kaneka Corporation, Otsu, Shiga, Japan

11:00 267

Large Area Nanocrystalline Silicon Based Multi-Junction Solar Cells with Superior Light Soaking Stability Xixiang Xu, Tining Su, Scott Ehlert, Ginger Pietka, Dave Beglau, Jinyan Zhang, Yang Li, Greg DeMaggio, Chris Worrel, Ken Lord, Guozhen Yue, Baojie Yan, Kevin Beernink, Arindam Banerjee, Jeff Yang, Subhendu Guha United Solar Ovonic LLC, Troy, MI, USA

11:30 268

Progress of SANYO’s R&D on Thin Film Silicon Solar Module Takeyuki Sekimoto, Hirotaka Katayama, Kazuya Murata, Mitsuhiro Matsumoto, Akinao Kitahara, Mitsuoki Hishida, Youichirou Aya, Wataru Shinohara, Makoto Nakagawa, Akira Terakawa, Makoto Tanaka ANYO Electric Co., Ltd., Gifu, Japan

11:45 269

Flexible Amorphous Silicon Solar Cells on Glass-Fabric Reinforced Coating Films in the Superstrate Configuration Jin-Wan Jeon1, Jong-San Im1, Sangil Park1, Liang Fang1, Jung Ho Jin2, Joon-Soo Kim2, Ji Hoon Ko2, SeungCheol Yang2, Byeong-Soo Bae2, Koeng Su Lim1 1KAIST, EE dept, Daejeon, South Korea, 2KAIST, MSE dept, Daejeon, South Korea

128


FR

IDA

Y A

M

10:30 - 12:00 PM Kaua’i 311

Area 2: Orals, CIGS & CdTe: Device and Module Reliability

Chair(s): Bill Shafarman, Jeff Britt

10:30 270

The Use of Second and Third-level Correlation Analysis for Studying Degradation in Polycrystalline Thin Film Solar Cells David S Albin1, Joseph A del Cueto1, Samuel H Demtsu2, Shubhra Bansal3 1National Renewable Energy Laboratory, Golden, CO, USA, 2Primestar Solar, Arvada, CO, USA, 3GE Global Research Center, Niskayuna, NY, USA

11:00 271

Intrinsic Stability of Thin-film CdS/CdTe Modules Samuel Demtsu1, Shubhra Bansal2, David Albin3 1Primestar Solar, Inc., Arvada, CO, USA, 2General Electric Global Research Center, Niskayuna, NY, USA, 3National Renewable Energy Laboratory, Golden, CO, USA

11:15 272

Damp-Heat Instability and Mitigation of ZnO-Based Thin Films for CuInGaSe2 Solar Cells F.J. John Pern, Steve H. Glick, Rajalakshmi Sundaramoorthy, Bobby To, XiaoNan Li, Clay DeHart, Stephen Glynn, Tomas Gennett, Rommel Noufi, Tim Gessert National Center for Photovoltaics, National Renewable Energy Laboratroy, Golden, CO, USA

11:30 273

Barrier Technology Providing Exceptional Stability of CIGS Devices Under Accelerated Damp Heat Conditions Marty W. DeGroot, Paul R. Elowe, Matt Stempki Dow Solar Solutions, The Dow Chemical Company, Midland, MI, USA

11:45 274

Encapsulation of CuInGaSe2 Solar Cells with ALD Al2O3 Flexible Thin-film Moisture Barrier: Stability under 1000 hour Damp Heat and UV Exposure Steven Hegedus1, P.F. Carcia2, R.S. Maclean2, Bradley Culver1 1Institute of Energy Conversion/Univ of Delaware, Newark, DE, USA, 2DuPont Research & Development, Experimental Station, Wilmington, DE, USA


129


FR

IDA

Y A

M10:30 - 12:00 PM Maui 316A/B

Area 4: Orals, Crystalline Silicon: Manufacturing and New Concepts

Chair(s): Kristian Peter, Bhushan Sopori

10:30 275

Kerf-Free Wafering: Technology Overview and Challenges for Thin PV Manufacturing Francois J Henley Silicon Genesis Corporation, San Jose, CA, USA

11:00 276

All Screen Printed Mass Produced Selective Emitter Solar Cells Homer Antoniadis Innovalight, Inc., Sunnyvale, CA, USA

11:15 277

Reaching Grid Parity Using BP SOLAR Crystalline Silicon Technology John H Wohlgemuth, Roger Clark, Jean Posbic, James Zahler, Daniel W. Cunningham, David Carlson BP Solar International, Frederick, MD, USA

11:30 278

A High-Throughput Silicon Epitaxy System for Photovoltaic Application Jianming Fu, Yan Rozenzon, Peijun Ding, Roger Anderson, Robert Trujillo, Steve Beese, David Z. Chen, Ben Chung, Heather Hu, Leon Ginzburg, Mark Mandelboym, Jonsong Tang, Chentao Yu, Guanghua Song, Benjamin Heng, Zheng Xu Sierra Solar Power, Inc., Fremont, CA, USA

11:45 279

Effect of SiO2 Thicknesses in Thermal-SiO2/PECVD-SiN Stacks on Surface Passivation of n-type Cz Silicon Substrates Yevgeniya Larionova1, Nils-P. Harder1,2, Rolf Brendel1,3 1ISFH - Institute for Solar Energy Research Hameln, Hameln, Germany, 2MBE - Institute of Electronic Materials and Devices, University of Hanover, Hanover, Germany, 3Institute of Solid-State Physics, University of Hanover, Hanover, Germany

130


FR

IDA

Y A

M

10:30 - 12:00 PM Ni’ihau 312

Area 1: Orals, Fundamentals & New Concepts: Quantum Dot Solar Cells

Chair(s): Christiana Honsberg, Ryugi Oshima, Alex Freundlich

10:30 280

Study of GaAs(Ti) Thin-Films as Candidates for IB Solar Cell Manufacturing Santiago Silvestre 1, Alfredo Boronat1, Luis Castañer1, David Fuertes2, Antonio Martí2, Antonio Luque2 1MNT-DEE-UPC, Barcelona, Spain, 2Instituto de Energía Solar- UPM, Madrid, Spain

11:00 281

Fabrication of Resonant Tunneling Structures for Selective Energy Contact of Hot Carrier Solar Cell Based on III-V Semiconductors Shuhei Yagi, Yoshitaka Okada Research Center for Advanced Science and Technology, The University of Tokyo, Tokyo, Japan

11:15 282

III-V Quantum Dot Enhanced Solar Cells Seth M. Hubbard1, Christopher Bailey1, Stephen Polly1, John Andersen1, David Forbes1, Ryne Raffaelle2 1Rochester Institute of Technology, Rochester, NY, USA, 2National Renewable Energy Laboratory, Golden, CO, USA

11:30 283

High-density and Well-ordered Si-Nanodisk Array with Controllable Band Gap and High Absorption Coefficient for All-Si Tandem Solar Cell Applications Chi-Hsien Huang1,4, Makoto Igarashi1,4, Mohd Fairuz Budiman1, Xuan-Yu Wang1,4, Ryuji Oshima2,4, Ichiro Yamashita3,4, Yoshitaka Okada2,4, Seiji Samukawa1,4 1Institute of Fluid Science, Tohoku University, Sendai, Japan, 2Research Center for Advanced Science and Technology, The University of Tokyo, Tokyo, Japan, 3Graduate School of Materials Science, Nara Institute of Science and Technology, Nara, Japan, 4Japan Science and Technology Agency (JST), CREST, Tokyo, Japan

11:45 284

Evidence of Intra-band Assisted Escape in Multi-Quantum Well Solar Cells Andenet Alemu, Alex Freundlich Photovoltaics and Nanostructures Laboratories, Center for Advanced Materials and Physics Department, University of Houston, Houston, TX, USA


131


FR

IDA

Y A

M10:30 - 12:00 PM Lana’i 314

Area 3: Orals, III-V’s & Concentrators: Advanced III-V Concentrator Cells

Chair(s): Sarah Kurtz, Mark Stan

10:30 285

Promises of Advanced Multi-Junction Solar Cells for the use in CPV Systems Frank Dimroth1, Simon P. Philipps1, Elke Welser1, René Kellenbenz1, Tobias Roesener1, Vera Klinger1, Eduard Oliva1, Marc Steiner1, Matthias Meusel2, Wolfgang Guter2, Andreas W. Bett1 1Fraunhofer ISE, Freiburg, Germany, 2AZUR Space, Heilbronn, Germany

10:45 286

Recent R&D Topics on Concentrator Mutli-junction Solar Cells and Materials Under Innovative Solar Cells’ R&D Project Masafumi Yamaguchi1, Hidetoshi Suzuki1, Yoshio Ohshita1, Nobuaki Kojima1, Tatsuya Takamoto2 1Toyota Technological Institute, Nagoya, Japan, 2Sharp Corporation, Nara, Japan

11:00 287

Inverted Thin Film InGaP/GaAs Tandem Solar Cells for CPV Applications using Eitaxial Lift Off Gerard J. Bauhuis1, Peter Mulder1, Erik J. Haverkamp1, John J. Schermer1, Lee J. Nash2, Dominic J.F. Fulgoni2, Ian M. Ballard2, Geoffrey Duggan2 1Radboud University Nijmegen, Nijmegen, Netherlands, 2Circadian Solar Ltd., Coventry, United Kingdom

11:15 288

Back Contacted and Small Form Factor GaAs Solar Cell Jose L. Cruz-Campa1, Gregory N. Nielson1, Murat Okandan1, Mark W. Wanlass2, Carlos A. Sanchez1, Paul J. Resnick1, Peggy J. Clews1, Tammy Pluym1, Vipin P. Gupta1 1Sandia National Laboratories, Albuquerque, NM, USA, 2National Renewable Energy Laboratory, Golden, CO, USA

11:30 289

Measurement of High Efficiency 1 cm2 AlGaInP/InGaAs/Ge Solar Cells with Embedded InAs Quantum Dots at up to 1000 Suns Continuous Concentration Christopher E. Valdivia 1, Jeffrey F. Wheeldon 1, Anthony SpringThorpe 2, Frank Shepherd 2, Bruno Riel3, Simon Fafard3, Vincent Aimez4, Richard Arès4, John Cook5, Trevor J. Hall1, Karin Hinzer1 1Centre for Research in Photonics, University of Ottawa, Ottawa, ON, Canada, 2Institute for Microstructural Sciences, National Research Council of Canada, Ottawa, ON, Canada, 3Cyrium Technologies Inc., Ottawa, ON, Canada, 4Centre de Recherche en Nanofabrication et en Nanocaractérisation CRN², Université de Sherbrooke, Sherbrooke, QC, Canada, 5OPEL Solar Inc., Shelton, CT, USA

11:45 290

InGaP/GaAs/InGaAs 41% Concentrator Cells using Bi-Facial Epigrowth Steven Wojtczuk1, Philip Chiu1, Xuebing Zhang1, Daniel Derkacs1, Chris Harris1, Daryl Pulver1, Mike Timmons2 1Spire Semiconductor, Hudson, NH, USA, 2Independent Consultant, Durham, NC, USA

132


10:30 - 12:00 PM Maui 316C

Area 8: Orals, PV Characterization: Module and Module Material Characterization

Chair(s): Ron Sinton

10:30 291

Performance Characterisation of Photovoltaic Modules Ralph Gottschlag Loughborough University, Loughborough, United Kingdom

11:00 292

Measuring Degradation Rates without Irradiance Data Steve Pulver1, Daniel Cormode1, Alexander Cronin1, Dirk Jordan2, Sarah Kurtz2, Ryan Smith2 1Department of Physics, University of Arizona, Tucson, AZ, USA, 2National Renewable Energy Laboratory (NREL), Golden, CO, USA

11:15 293

Quantitative Analysis and Extraction of Cell Parameters from Interconnected Thin Film Modules Through LBIC-Voltage Scans Jonathan M Frey1, Steven S Hegedus2, Chris Thompson2 1PrimeStar Solar, Inc., Arvada, CO, USA, 2Institute of Energy Conversion, Newark, DE, USA

11:30 294

Reliability of Copper-Ribbons in Photovoltaic Modules under Thermo-Mechanical Loading Rico Meier1, Frank Kraemer1, Steffen Wiese1, Klaus-Juergen Wolter2, Joerg Bagdahn1 1Fraunhofer Center for Silicon Photovoltaics, Halle (Saale), Germany, 2TU Dresden Electronics Packaging Lab, Dresden, Germany

11:45 295

Infrared Birefringence Imaging of Residual Stress and Bulk Defects in Multicrystalline Silicon Vidya Ganapati1,2, Sergio Castellanos1, Stephan Schoenfelder2,1, Sebastian Oener3,1, Tonio Buonassisi1 1Massachusetts Institute of_Technology, Cambridge, MA, USA, 2Fraunhofer Center for Silicon_Photovoltaics, Halle, Germany, 3University of Konstanz, Konstanz, Germany

12:00 - 1:00 PM Maui 316A/B

Closing Session

FR

IDA

Y A

M


133


TUESDAY JUNE 22POSTER PRESENTATIONS

POSTER HALL MAP ON PAGES 12-13

10:30 - 12:00 PM Kamehameha Exhibit Hall III.b

Area 4: Posters, Crystalline Silicon: Device Fabrication and Characterization

Chair(s): Matthias Hörteis, Francois Henley (296-H25) Ion Implantation as a Potential Alternative for the Formation of Front Surface Fields for IBC Cells. Monica Aleman, Bartek J. Pawlak, Tom Janssens, Erik Rosseel, Niels E. Posthuma, Jef Poortmans. IMEC, Heverlee, Belgium. (297-H29) Effect of Junction Interface Modification of Silicon Heterojunction Solar Cells. Jesse Appel, Lulu Zhang, Ujjwal Das, Steven Hegedus, Swapna Mudigonda, Robert Birkmire, Jim Rand. University of Delaware - Institute of Energy Conversion, Newark, DE, USA. (298-H33) Copper as Conducting Layer in Advanced Front Side Metallization Processes for Silicon Solar Cells, Exceeding 20% Efficiency on Printed Seed Layers. Jonas M Bartsch, Andrew Mondon, Christian Schetter, Matthias Hörteis, Stefan W Glunz. Fraunhofer ISE, Freiburg, Germany. (299-I3) n-type Silicon Solar Cells with Amorphous/Crystalline Silicon Heterojunction Rear Emitter. Martin Bivour, Chistoph Meinhardt, Damian Pysch, Martin Hermle, Stefan W. Glunz. Fraunhofer Institute for Solar Energy Systems, Freiburg, Germany. (300-I7) The Etchback Selective Emitter Technology and its Application to Multicrystalline Silicon. Felix Book, Bernd Raabe, Stefan Braun, Amir Dastgheib-Shirazi, Giso Hahn. University of Konstanz, Konstanz, Germany. (301-I11) High-Ramp Industrial Firing Processes for the Metallization of Crystalline Silicon Solar Cells. Frank J. Bottari, Wendy Montanez-Ortiz, David C. Wong, Paul J. Richter, Fred Dimock, Tianming Bao. BTU International, North Billerica, MA, USA. (302-I15) Characteristics of MIS Solar Cells Using A Sputtering SiO2 Insulating Layer. Tzu-Yueh Chang1,2, Chun-Lung Chang2, Hsin-Yu Lee1, Po-Tsung Lee1,2. 1Department of Photonics & Institute of Electro-Optical Engineering, National Chiao Tung University, Hsinchu, Taiwan, 2Department of Photonics & Display Institute, National Chiao Tung University, Hsinchu, Taiwan. (303-I19) Two Step Ni/Cu Metallization for Commercial c-Si Solar Cells: 1 to 10 Suns. Vikrant Chaudhari, Chetan Solanki. Department of Energy Science and Engineering, Indian Institute of Technology Bombay, Mumbai, India. (304-I23) 12.6% Efficient Freestanding 30 μm Thin Silicon Solar Cell Using a-Si/c-Si Heterostructure. Bhumika Chhabra1, Robert L. Opila1, Christiana Honsberg2. 1University of Delaware, Newark, DE, USA, 2Arizona State University, Tempe, AZ, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

134


TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

(305-I27) Fabrication of Metal Grid on Silicon-Based Solar Cell by Electrochemical Deposition and Microcontact Print. Chih-Hsien Lin1, Wei-Lin Chen3, Chen-Hsun Du2,4, Chi-Chao Wan1, Yung-Yun Wang1. 1Department of Chemical Engineering, National Tsing Hua University, Hsinchu, Taiwan, 2Photovoltaics Technology Center, Industrial Technology Research Institute (ITRI), Hsinchu, Taiwan, 3Department of Materials Sceince, National Tsing Hua University, Hsinchu, Taiwan, 4Institute of NanoEngineering and MicroSystems, National Tsing Hua University, Hsinchu, Taiwan. (306-I31) Improvements of Voc by Selective Emitter Pattern Optimization in Screen Printed Crystalline Si Solar Cells. Kyeong-Yeon Cho1, Il-Hwan Kim1, Dong-Joon Oh1, Ji-Myung Shim1, Eun-Joo Lee1, Hyun-Woo Lee1, Jun-Young Choi1, Ji-Sun Kim1, Soo-Hong Lee2, Hae-Seok Lee1. 1Shinsung holdings, Seongnam-Si, South Korea, 2Sejong University, Seoul, South Korea. (307-J1) Investigation of the Effect of Compensation Ratio (RC) on Solar Cells Fabricated with Solar Grade (SoG) Czochralski Silicon. J. Camacho-Cuardrado1, I. B. Cooper1, A. Ebong1, G. Bausch2, W. Tulloch3, G. Burns3, G. Beaucarne3, A. Rohatgi1. 1University Center of Excellence in Photovoltaics Research and Education, School of Electrical and Computer Engineering, Georgia Institute of Technology, Atlanta, GA, USA, 2Hemlock Semiconductor Corporation, Hemlock, MI, USA, 3Dow Corning Corporation, Midland, MI, USA. (308-J5) High Speed Non-Contact Printing for Solar Cell Front Side Metallization. Kenneth H. Church, Xudong Chen. nScrypt Inc., Orlando, FL, USA. (309-J9) Thin and Small Form-Factor Cells: Simulated Behavior. Jose L. Cruz-Campa1,2, David Zubia2, Murat Okanda1, Paul J. Resnick1, Robert K. Grubbs1, Peggy J. Clews1, Ralph W. Young1, Vipin P. Gupta1, Gregory N. Nielson1. 1Sandia National Laboratories, Albuquerque, NM, USA, 2University of Texas at El Paso, El Paso, TX, USA. (310-J13) Crystalline Silicon Solar Cells with Doped Epitaxial Silicon Films Obtained Entirely by Low-Temperature PECVD. Jérôme Damon-Lacoste1, Martin Labrune1,2, Stefano Granata1, Dmitri Daineka2, Pere Roca i Cabarrocas2. 1TOTAL S.A., Gas & Power – R&D Division, Courbevoie, France, 2Laboratoire de Physique des Interfaces et Couches Minces, CNRS-Ecole Polytechnique, Palaiseau, France. (311-J17) Investigation of Hetero-interface and Junction Properties in Silicon Heterojunction Solar Cells. Ujjwal Das, Steven Hegedus, Lulu Zhang, Jesse Appel, Jim Rand, Robert Birkmire. Institute of Energy Conversion, University of Delaware, Newark, DE, USA. (312-J21) High Efficiency Silicon Solar Cells with Ink Jetted Seed and Plated Grid on High Sheet Resistance Emitter. Abasifreke Ebong1, Brian Rounsaville1, Ian Cooper1, Keith Tate1, Ajeet Rohatgi1, S. Glunz2, M. Horteis2, A. Mette3, M. Gundermann3, M. Dovrat4, R. Even4, H. Gothait4. 1Georgia Institute of Technology, Atlanta, GA, USA, 2Fraunhofer Institute for Solar Energy Systems, Freiburg, Germany, 3Q-Cells, OT Thalheim Sonnenallee, Germany, 4Xjet Solar, Rehovot, Israel.


135


TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS(313-J25) Electronic Surface Passivation for Crystalline Silicon

Solar Cells by a-Si1-xCx:H. Christian Ehling, Dorian Treptow, Gerhard Bilger, Markus B. Schubert. Universität Stuttgart, Stuttgart, Germany. (314-J29) Space Charge Limited Current Effects in Silicon At High Injection Levels. Ari D Feldman1, Richard K Ahrenkiel1,2. 1Colorado School of Mines - Metallurgy and Materials Department, Golden, CO, USA, 2Colorado School of Mines - Renewable Energy Materials Research Science and Engineering Center, Golden, CO, USA. (315-J33) Photographic Distinction of Defects in Polycrystalline Si by Spectroscopic Electroluminescence. Takashi Fuyuki, Ayumi Tani, Sinichiro Tsujii, Emi Sugimura. Nara Institute of Science and Technologu, Ikoma, Nara, Japan. (316-K3) Explanation of the Device Operation Principle of Amorphous Silicon/Crystalline Silicon Heterojunction Solar Cell and Role of the Inversion of Crystalline Silicon Surface. Kunal Ghosh, Stainslau Herasimenka, Christiana Honsberg, Stuart Bowden. Arizona State University, Tempe, AZ, USA. (317-K7) Photothermal Characterization by Atomic Force Microscopy around Grain Boundary in Multicrystalline Silicon Material. Kenji Hara1, Takuji Takahashi1,2. 1Institute of Industrial Science, The University of Tokyo, Tokyo, Japan, 2Institute for Nano Quantum Information Electronics, The University of Tokyo, Tokyo, Japan. (318-K11) 2D Modeling of Silicon Heterojunction Interdigitated Back Contact Solar Cells. Stanislau Herasimenka, Kunal Ghosh, Stuart Bowden, Christiana Honsberg. School of Electrical, Computer and Energy Engineering, Arizona State University, Tempe, AZ, USA. (319-K15) Fast and Precise Resistance Characterization of Laser Drilled and Metalized Vias. Michael Menkoe, Rene Hoenig, Hermann Reitenbach, Florian Clement, Daniel Biro. Fraunhofer Institute for Solar Energy Systems (ISE), Heidenhofstrasse 2, D-79110 Freiburg, Germany. (320-K19) Beam shaping – the Key to High Throughput Selective Emitter Laser Processing with a Single Laser System. Ulrich Jäger1, Peter Oesterlin2, Ralf Preu1. 1Fraunhofer ISE, Freiburg, Germany, 2Innovavent GmbH, Göttingen, Germany. (321-K23) A Study into the Formation and Characterisation of Electroless Nickel Silicide for Laser Doped Solar Cells. Anahita Karpour, Stuart R. Wenham. UNSW, Sydney, Australia. (322-K27) The Importance of Surface Roughness in the Adhesion of Electroless-Plated Nickel in Inkjet Printed Grooves. Anahita Karpour, Stuart R. Wenham. UNSW, Sydney, Australia. (323-K31) Transparent Silicon Solar Cells: Design, Fabrication, and Analysis. Christopher Kerestes, Yi Wang, Kevin Shreve, Allen Barnett. University of Delaware, Newark, DE, USA. (324-L1) Electrical Properties and Boundary Structures in Cast-Grown Polycrystalline Silicon. Takuto Kojima1, Yoshio Ohshita1, Tomihisa Tachibana2, Atsushi Ogura2, Masafumi Yamaguchi1. 1Toyota Technological Institute, Nagoya, Japan, 2Meiji University, Kawasaki, Japan.

136


TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

(325-L5) Industrial Large Area n-type Cz-Si Solar Cells with Aluminum Rear Emitter with Stable Efficiencies. Radovan Kopecek1, Andreas Halm1, Lacramonia Popescu1, Kristian Peter1, Miquel A. Vázquez2. 1ISC Konstanz, Konstanz, Germany, 2Isofotón, Málaga, Spain. (326-L9) High Performance Solar Cells Made From 100% UMG Silicon Obtained Via The PHOTOSIL Process. François Cocco1, Béatrice Drevet2, Jed Kraiem3, Nicolas Enjalbert2, Sébastien Dubois2, Denis Camel2, Delphine Grosset-Bourbange1, Roland Einhaus3, David Pelletier2, Thomas Margaria1. 1FerroPEM, Chambéry, France, 2CEA-INES, Le Bourget du Lac, France, 3Apollon Solar, Lyon, France. (327-L13) Low Temperature Silicon Epitaxy using Rapid Thermal Chemical Vapor Deposition (RTCVD) for Solar Cell application. Donny Lai1, Yew Heng Tan1, Chin Hin Oon2, Vinodh Shanmugam2, Duen Yang Ong3, Chuan Seng Tan1. 1Nanyang Nanofabrication Centre (N2FC), Singapore, Singapore, 2Solar Energy Research Insitute of Singapore (SERIS), Singapore, Singapore, 3School of Materials Science and Engineering, Singapore, Singapore. (328-L17) The Potential Efficiency of Laser Doped Solar Cells using Photoluminescence Imaging. Eunjoo Lee1, Hyunwoo Lee1, Ilhwan Kim1, Junyoung Choi1, Dongjun Oh1, Jimyung Shim1, Kyungyeun Cho1, Jisun Kim1, Soohong Lee2, Hae-Seok Lee1, Brett Hallam3, Stuart Wenham3. 1R&D center, Shinsung Holdings, Gyeonggi-do, Korea, 2Department of Electronic Engineering, Sejong University, Seoul, Korea, 3ARC Photovoltaics Center of Excellence, University of New South Wales, Sydney, Australia. (329-L21) High Efficiency Selective Emitter Enabled Through Patterned Ion Implantation. Russell J Low1, Atul Gupta1, Nicholas Bateman1, Deepak Ramappa1, Paul Sullivan1, Wesley Skinner1, James Mullin1, Stefan Peters2, Harold Weiss-Wallrath2. 1Varian Semiconductor Equipment Associates, Gloucester, MA, USA, 2Q-Cells AG, Thalheim, Germany. (330-L25) Rear Side Point Contacts by Inline Thermal Evaporation of Aluminum. Christoph P. Mader1, Jens Müller1, Sebastian Gatz1, Thorsten Dullweber1, Rolf Brendel1, 2. 1IInstitute of Solar Energy Research Hamelin (ISFH), Hamelin, Germany, 2Institute of Solid-State Physics, University of Hanover, Hanover, Germany. (331-L29) HW-CVD Deposited mc-Si:H for the Inverted Heterojunction Solar Cell. Yasuhiro Matsumoto1, Mauricio Ortega1, Frank Wünsch2. 1Electrical Engineering Department, Centro de Investigación y de Estudios Avanzados del IPN, Mexico, Mexico, 2Dept. Solare Energetik Helmholtz-Zentrum Berlin für Materialien und Energie Lise-Meitner-Campus, Berlin, Germany. (332-L33) Impact of Metal Contact Misalignment in Selective Emitter Solar Cells. Andreas Meisel, Michael Burrows, Malcolm Abbott, Francesco Lemmi. Innovalight, Inc., Sunnyvale, CA, USA. (333-M3) PV Concentrator Cells Complex Impedance Under the Bias in the Dark. Vladimir Saly, Milan Perny, Martin Kusko, Juraj Packa. Slovak University of Technology, Bratislava, Slovakia.


137


TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS(334-M7) Localized Doping Using Silicon Ink Technology. K.

Alberi1, H.R. Moutinho1, R.C. Reedy1, M.J. Romero1, D.L. Young1, G. Scardera2, E. Rogojina2, M. Kelman2, D. Poplavskyy2, F. Lemmi2, H. Antoniadis2. 1National Renewable Energy Laboratory, Golden, CO, USA, 2Innovalight Inc., Sunnyvale, CA, USA. (335-M10) High-Efficiency Crystalline Si Thin Film Solar Cells with Si Nanopillar Array Textured Surfaces. Junshuai Li, She Mein Wong, Yali Li, HongYu Yu. School of EEE / Nanyang Technological University, Singapore, Singapore.

10:30 - 12:00 PM Kamehameha Exhibit Hall III.c

Area 5: Posters, Amorphous, nc, & Film Silicon: Devices, Modules, and Novel Concepts

Chair(s): Hitoshi Sai, Paul Stradins (336-M14) Modification of Light Scattering Properties of ZnO:B grown by Low Pressure Chemical Vapour Deposition using Wet Chemical Etching. Sonya Calnan1, Clement David2, Niklas Papathanasiou2, Rutger Schlatmann1, Bernd Rech1,3. 1PVcomB (Competence Center for Thin Film and Nanotechnology in Photovoltaics), Helmholtz Zentrum Berlin für Materialien und Energie GmbH, Schwarzschildstr. 3, D-12489, Berlin, Germany, 2Inventux Technologies AG, Wolfener Str. 23, D-12681, Berlin, Germany, 3Institut für Silizium-Photovoltaik, Helmholtz Zentrum Berlin für Materialien und Energie GmbH, Kekuléstr. 5, D-12489, Berlin, Germany. (337-M16) Optimization of ZnO/Ag Back Reflector for Silicon Thin-Film Solar Cell Application. Jun-Sik Cho, Sanghun Baek, Jeong Chul Lee, Sang-Hyun Park, Jinsoo Song, Kyung Hoon Yoon. Korea Institute of Energy Research, Daejeon, South Korea. (338-M18) Amorphous Silicon Solar Cells on Plastic-based Photonic Structures. Sambit Pattnaik1, Rana Biswas1, Vikram L. Dalal1, Dennis Slafer2, Jin Ji2. 1Iowa State University, Ames, IA, USA, 2Lightwave Power, Cambridge, MA, USA. (339-M20) Simulations of Carrier Recombination and Effects on Efficiency for Columnar-Grained Crystalline Silicon Film Solar Cells. Michael G. Deceglie, Michael D. Kelzenberg, Harry A. Atwater. California Institute of Technology, Pasadena, CA, USA. (340-M22) High Rate Deposition of a-Si and a-SiGe Solar Cells near Depletion Condition. Qi H Fan1, Guofu Hou1, Xianbo Liao1, Xianbi Xiang1, Changyong Chen1, William B Ingler1, Nirupama Adiga1, Xinmin Cao2, Wenhui Du2, Xunming Deng1,2. 1The University of Toledo, Toledo, OH, USA, 2Xunlight Corporation, Toledo, OH, USA. (341-M24) Tungsten Oxide as a p-type Window Material in Amorphous Silicon Solar Cells. Liang Fang, Seung Jae Baik, Koeng Su Lim, Seung Hyup Yoo, Jin Wan Jeon, Sang Jung Kang, Myung Soo Seo. Department of Electrical Engineering, Korea Advanced Institute of Science and Technology (KAIST), Daejeon, Korea.

138


(342-M30) Optimization of Semi-Transparent Amorphous and Microcrystalline Silicon Solar Cells Fabricated on Glass and PEN Substrates. Ehsanollah Fathi, Andrei Sazonov. University of Waterloo, Waterloo, ON, Canada. (343-M32) Photocurrent Enhancements in Amorphous Silicon Solar Cells by Embedded Metallic Nanoparticles. C. I. Ho1, C. H. Yang2, C. J. Huang2, D. J. Yeh2, Y. S. Chu2, C. Y. Hsueh2, W. C. Tu2, T. Y. Ma2, S. C. Lee1,2. 1Department of Electrical Engineering Graduate Institute of Photonics and Optoelectronics National Taiwan University, Taipei 10617, Taiwan, Taipei, Taiwan, 2Department of Electrical Engineering Graduate Institute of Electronics Engineering National Taiwan University, Taipei 10617, Taiwan, Taipei, Taiwan. (344-M34) ZnO Films Prepared by Two-Step MOCVD Process for Use as Front TCO in Silicon-Based Thin Film Solar Cells. Aswin Hongsingthong1, Ihsanul Afdi Yunaz1, Shinsuke Miyajima1, Makoto Konagai1,2. 1Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan, 2Photovoltaics Research Center (PVREC), Tokyo Institute of Technology, Tokyo, Japan. (345-N2) Device Modeling of a Micromorph Tandem Solar Cell Using AMPS-1D. J.Y. Huang1, C. W. Hsu1, Jia-Min Shieh1,2, Peichen Yu1. 1Department of Photonics and Institute of Electro-Optical Engineering, Hsinchu, Taiwan, 2National NanoDevice Laboratory, Hsinchu, Taiwan. (346-N4) Optical Design of Multi-Stacked Intermediate Layer with Wavelength-Selective Reflectance for a-Si:H/µc-Si:H Tandem Solar Cells. Bancha Janthong1, Ihsanul Afdi Yunaz1, Hidetada Tokioka2, Shinsuke Miyajima1, Makoto Konagai1,3. 1Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan, 2Advanced Technology R&D Center, Mitsubishi Electric Corporation, Amagasaki, Japan, 3Photovoltaics Research Center (PVREC), Tokyo Institute of Technology, Tokyo, Japan. (347-N6) Effect of Boron-Doping on Transparent Conducting Al Doped ZnO Films for Thin Film Solar Cells. Dong-Won Kang, Seung-Hee Kuk, Sun-Jae Kim, Jeong-Soo Lee, Min-Koo Han. Seoul National University, Seoul, Korea. (348-N8) Amorphous Silicon Solar Cells with Novel Mesh Substrates for Concentrator Photovoltaic Applications. Shunsuke Kasashima1, Ryohei Uzawa1, Ihsanul Afdi Yunaz1, Yasuo Kakihara2, Shinsuke Miyajima1, Akira Yamada1,3, Makoto Konagai1,3. 1Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan, 2R&D Div. TODA KOGYO CORP., Hiroshima, Japan, 3Photovoltaics Research Center (PVREC), Tokyo Institute of Technology, Tokyo, Japan. (349-N10) Hetero-Junction Microcrystalline Silicon Solar Cells with Wide-Gap p-mc-Si1-xOx:H Layer. Taweewat Krajangsang1, Shunsuke Kasashima1, Ihsanul Afdi Yunaz1, Shinsuke Miyajima1, Makoto Konagai1,2. 1Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan, 2Photovoltaics Research Center (PVREC), Tokyo Institute of Technology, Tokyo, Japan. (350-N12) Optical Modelling of Light Trapping in Thin Film Silicon Solar Cells using the FDTD Method. Juergen Lacombe, Stefan Geissendoerfer, Karsten von Maydell, Carsten Agert. EWE Research Center for Energy Technology NEXT ENERGY, Oldenburg, Germany.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


139


(351-N14) Numerical Simulation and Experimental Investigation of a-Si/a-SiGe Tandem Junction Solar Cells. Qi Hua Fan1, Xianbo Liao1, Changyong Chen1, Xianbi Xiang1, Guofu Hou1, William Ingler1, Nirupama Adiga1, Shibin Zhang2, Wenhui Du2, Xinmin Cao2, Xunming Deng1,2. 1The University of Toledo, Toledo, OH, USA, 2Xunlight Corp., Toledo, OH, USA. (352-N16) Fabrication and Characterization Silicon Thin Film Solar Cells Deposited by HF-PECVD. Shui-Yang Lien1, Yu-Chih Ou1, Yun-Shao Cho1, Chao-Chun Wang3, Chia-Fu Chen1, Wen-Ching Sun2, Dong-Sing Wuu3. 1Department of Materials Science and Engineering, MingDao University, ChungHua, Taiwan, 2Material and Chemical, Hsinchu, Taiwan, 3Department of Materials Science and Engineering, Nation Chung Hsing University, Taichung, Taiwan. (353-N18) Modeling The Haze of Highly Textured Transparent Conducting Oxide. Chien-chung Lin, Wei-Lin Liu, Chi-Ying Hsieh. National Chiao-Tung University, Tainan County, Taiwan. (354-N20) Enhanced Efficiency in Thin-Film a-Si Cells using Isolated Nano Structures. Magued Nasr1, Murray McCutcheon2, Cy Herring3. 1Lightwave Power Inc., Cambridge, MA, USA, 2Harvard University, Cambridge, MA, USA, 3Sencera International, Charlotte, NC, USA. (355-N22) Co-relation between Capacitance-Voltage, Conductance-Voltage and Photoconductive Properties of the as-Deposited and Annealed a-Si/SiNx Multilayer Films Prepared using Hot-Wire CVD. Ashish K Panchal1, Dharmendra K Rai2, Meril Mathew2, Chetan S Singh2. 1SVNIT, Surat Gujarat, India, 2IIT Bombay, Mumbai, India. (356-N24) Light Absorption Enhanced Structure of Thin Film Silicon Solar Cell. Sungjin Park, Beomjun Kim, Haifeng Jin, Changmin Keum, Yangwook Heo, Byungseong Bae. School of Display Engineering, Hoseo University, Asan, Korea. (357-N30) Polycrystalline Silicon Thin Film Solar Cells on Glass-Ceramic and Metallic Foils Employing AIC Grown Seed Layers. Pathi Prathap1, O Tuzun1, D Madi1, A Slaoui1, S Vallon2, C Ducros3. 1InESS-CNRS/UdS, 23 rue du loess, F-67037, Strasbourg, France, 2Corning European Technology Center, 7bis avenue de Valvins, 77210, Avon, France, 3CEA-LITEN-DTNM-LTS, 17, rue des martyrs, 38054, GRENOBLE Cedex 9, France. (358-N32) Characterization of Experimental Textured ZnO:Al Films for Thin Film Solar Cell Applications and Comparison With Commercial and Plasmonic Alternatives. David N. R. Payne1, Stuart A. Boden1, Owain D. Clark1, Alan E. Delahoy2, Darren M. Bagnall1. 1University of Southampton, Southampton, United Kingdom, 2EPV Solar, Robbinsville, NJ, USA. (359-N34) Implementation of Nanoclusters in Intermediate Reflective Layers. Mikhail V. Ponomarev, Haile Takele Beyene, Mariadriana Creatore, M.C.M. van de Sanden. Eindhoven University of Technology, Eindhoven, Netherlands. (360-O2) Internal Electric Field and Fill Factor of Amorphous Silicon Solar Cells. Arvind V. Shah1, Janez Krc 2, Michael E Stückelberger1, Fanny Sculati-Meillaud 1, Christophe Ballif1, Matthieu Despeisse1. 1IMT/EPFL PV Lab, NEUCHATEL, Switzerland, 2University of Ljubljana, Ljubljana, Slovakia.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

140


(361-O4) Efficient Light Trapping Structure in Thin Film Silicon Solar Cells. Xing Sheng1, Jifeng Liu1, Inna Kozinsky2, Anuradha M Agarwal1, Jurgen Michel1, Lionel C Kimerling1. 1Department of Materials Science and Engineering, Massachusetts Institute of Technology, Cambridge, MA, USA, 2Robert Bosch LLC, Research and Technology Center, Palo Alto, CA, USA. (362-O6) Omnidirectional Optical Transmission by Optimized Nano-Structures of Solar Cells. Jaesung Son, Lalit Verma, Aaron Danner, Charanjit Bhatia, Hyunsoo Yang. Department of Electrical and Computer Engineering, National University of Singapore, Singapore, Singapore. (363-O8) The Low-Loss Plasmonic Mode for Light Confinement in Silicon-Based Thin-Film Solar Cells. Fu-Ji Tsai, Jen-Hung Wang, Chih-Hung Yeh. NexPower Technology Corporation, Taichung County, Taiwan. (364-O10) Decreasing Performance of An Amorphous Silicon Grid-connected System That was Install in Thailand. Napat Watjanatepin, Chaiyant Boonmee. Rajamangala University of Technology Suvarnabhumi, Muang Nonthaburi, Thailand. (365-O12) Orientation Selected Epitaxy for Grain Enlargement of AIC Poly-Si Seed Layers. Sung-Yen Wei1, Sheng-Min Yu2, Hung-His Lin1, Wei Chen1, Chun-Jen Chen1, Tzer-Shen Lin2, Chuen-Horng Tsai1, Fu-Rong Chen1. 1National Tsing Hua University, Hsinchu, Taiwan, 2Industrial Technology Research Institute, Chutung, Hsinchu, Taiwan. (366-O14) Blaze Gratings as Light Trapping Structures for Enhancing Cell Efficiency of Thin-film Crystalline Silicon Solar Cells. Yih-Peng Chiou1,2, Shin-Yi Wu 1, Cheng-Yen Chen1. 1Institute of Photonics and Optoelectronics, National Taiwan University, Taipei, Taiwan, 2Department of Electrical Engineering, National Taiwan University, Taipei, Taiwan. (367-O16) ZnO Films with Very High Haze Ratio Prepared by MOCVD Technique. Ihsanul A Yunaz1, Aswin Hongsingthong1, Liping Zhang1, Shinsuke Miyajima1, Makoto Konagai1,2. 1Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan, 2Photovoltaics Research Center (PVREC), Tokyo Institute of Technology, Tokyo, Japan. (368-O18) Optical Absorption in Microstructured Crystalline Silicon Thin Films. Salvador Guel Sandoval1, Khizar Khan2, Dave Modisette2, John Anderson3, Ron Manginell3, Nowshad Amin4, Kamaruzzaman Sopian4, Saleem H. Zaidi2. 1Instituto de Investigación en Comunicación Óptica, of UASLP, Mexico, 2Gratings, Inc., Albuquerque, NM, USA, 3Sandia National Laboratories, Albuquerque, NM, USA, 4University Kebangsaan Malaysia, Bangi, Malaysia. (369-O20) A Method Used to Check the Effect of Up-Conversion Material on the Performance of Solar Cells. Xiaodan Zhang, Dongfeng Wang, Changchun Wei, Shaozhen Xiong, Xinhua Geng, Ying Zhao. Institute of Photo-electronic Thin Film Devices and Technology of Nankai University, Tainjin, China.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


141


10:30 - 12:00 PM Kamehameha Exhibit Hall III.d

Area 6: Posters, Organic Photovoltaics: Organic Photovoltaics

(370-O21) New Candidates for Near-Infra-Red-Absorbing Active Layers in Multijunction Organic Photovoltaics: Characterization and Performance. Chris J Collison1,2, Jason Staub1, Amber Monfette1, Susan D, Spencer1,2, Jessica Alexander1,2, Harry Hu1, Paul Jarosz1, Annick Anctil1. 1NanoPower Research Laboratory, RIT, Rochester, NY, USA, 2Department of Chemistry, RIT, Rochester, NY, USA. (371-O23) Low Band Gap Co-Polymers with Alternating Donor and Acceptor Moieties for Applications in Organic Photovoltaics. Zbyslaw R. Owczarczyk, Ross Larsen, Wade A. Braunecker, David S. Ginley, Dana C. Olson. National Renewable Energy Laboratory, Golden, CO, USA. (372-O29) Triphenylamine-Based Star-Shaped Absorbers with Tunable Energy Levels for Organic Photovoltaics. Scott R. Hammond, Andres Garcia, Alexandre Nardes, Eric Knoll, Muhammet E. Kose, Ross Larsen, Nikos Kopidakis, Zbyslaw Owczarczyk, Dana C. Olson, David S. Ginley. National Renewable Energy Laboratory, Golden, CO, USA. (373-O31) Design and Fabrication of Linear Pixel Arrays for Organic Photovoltaic Modules to Achieve Scalable Power Output. Kang-Shyang Liao1, Sampath Dias1, Nigel J Alley1,2, Soniya D Yambem1, Amrita Haldar1, Seamus A Curran1. 1University of Houston, Houston, TX, USA, 2Dublin City University, Dublin, Ireland. (374-O33) Bulk p-i-n Hetero-Junction Solar Cells Made from Hyperbranched Phthalocyanine Polymers. Yong Li, Lixin Xiao, Xingzhong Yan, David Galipeau. Advanced Photovoltaics & Department of Electrical Engineering and Computer Science, South Dakota State University, Brookings, SD, USA. (375-P1) Photo-Carrier Dynamics of Composite and Multi-Layered Films of Zinc Phthalocyanine and C60 Measured by Time-Resolved Terahertz Spectroscopy. Joseph S. Melinger1, Paul A. Lane1, Okan Esenturk2, Edwin J. Heilweil2. 1Naval Research Laboratory, Washington, DC, USA, 2National Institutes of Standards and Technology, Gaithersburg, MD, USA. (376-P3) Improvement of Photo-Current Density by Alternative Deposition Method for Organic Photovoltaic Cell. Tetsuya Taima1,2, Yosei Shibata1,3, Jun Sakai4, Tetsuhiko Miyadera1, Toshihiko Yamanari1, Yuji Yoshida1. 1RCPV. AIST., Tsukuba, Japan, 2JST-PRESTO, Kawaguchi, Japan, 3Yamagata Univ., Yonezawa, Japan, 4Panasonic Electric Works, Kadoma, Japan. (377-P5) Photoinduced Energy Transfer in Conjugated Polymer/6,6-Phenyl-C61-Butyric acid Methyl Ester Blend Films using Femtosecond Fluorescence Upconversion Technique. Zhiling Zhang, Yu Xie, Qiquan Qiao, David Galipeau, Xingzhong Yan. South Dakota State University, Brookings, SD, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

142


(378-P7) Improved Performance of Inverted-type Organic Solar Cells by Surface Modification on Polymer Thin Film. Ing-Jye Wang, Shu-Chia Shiu, Ming-Yi Lin, Yu-Hong Lin, Ching-Fuh Lin. National Taiwan University, Taipei, Taiwan. (379-P9) Photo-Degradation and its Recovery by Thermal Annealing in Polymer-Based Organic Solar Cells. T Yamanari1, H Ogo1, T Taima1,2, J Sakai3, J Tsukamoto4, Y Yoshida1. 1National Institute of Advanced Industrial Science and Technology (AIST), Tsukuba, Japan, 2JST-PRESTO, Kawaguchi, Japan, 3Panasonic Electric Works, Ltd., Kadoma, Japan, 4Toray Industries, Inc., Ohtsu, Japan. (380-P11) Employing TiO2 Nanorods to Improve Inverted Polymer Solar Cells. Lin Yu-Hong1, Huang Jing-Shun2, Wang Ing-Jye2, Lin Ming-Yi2, Wu Wen-Hao2, Huang Guo-Dong3, Su Wei-Fang3, Lin Ching-Fuh1,2. 1 Graduate Institute of Electronics Engineering, National Taiwan University, Taipei, Taiwan, 2Graduate Institute of Photonics and Optoelectronics, National Taiwan University, Taipei, Taiwan, 3Department of Material Science and Engineering, National Taiwan University, Taipei, Taiwan. (381-P13) Inorganic/Organic Heterojunction Solar Cell Fabricated with ZnO Nanowires. Sung Hyun Kim, Sung Hwak Park, Kyoung Il Lee, Seon Min Kim, Jin Woo Kim. KETI, Seongnam-Si, South Korea. (382-P15) PEDOT:PSS Layers as Replacements for the Transparent Conductive Coatings of Organic Solar Cells. Stefan Schwertheim, Oliver Grewe, Ralf Pichner, Thomas Mueller, Wolfgang R. Fahrner. University of Hagen, Hagen, Germany. (383-P17) Effects of Removing PEDOT:PSS from Organic Solar Cells With Carbon Nanotube Electrodes. Teresa M. Barnes, Jeremy D. Bergeson, Robert C. Tenent, Brian A. Larsen, Jeffrey L Blackburn, Glenn Teeter, Jao van de Lagemaat. National Renewable Energy Lab, Golden, CO, USA. (384-P19) Increased Absorption and Conversion In Ternary Bulk Heterojunction Systems of CdSe Nanoparticle/Methyl Viologen Composites, Conjugated Polymers, and Fullerenes. Eric D Peterson1, Gregory M. Smith1, Minglai Fu2, Richard D. Adams2, David L. Carroll1. 1Wake Forest University, Winston-Salem, NC, USA, 2University of South Carolina, Columbia, SC, USA. (385-P21) The Characterization of P-type Metal Oxide Buffer layer for BHJ Solar Cell. Dong Chan Lim1, Young Tae Kim1, Won Hyun Shim 1, Yongsoo Jeong1, Kyu Hwan Lee1, Yang Do Kim2. 1Korea Institute Materals Science, Changwon, Korea, 2Pusan National University, Busan, Korea. (386-P23) All-Solution-Processed-Inverted Polymer Solar Cells on PET Substrates with CuOx Thin Film as an Anode Interlayer. Ming-Yi Lin1, Chun-Yu Lee1, Shu-Chia Shiu1, Jen-Yu Sun1, Yu-Hong Lin1, Wen-Hau Wu1, Ching-Fuh Lin1,2. 1Graduate Institute of Photonics and Optoelectronics, National Taiwan University, Taipei, Taiwan, 2Graduate Institute of Electronics and Engineering, National Taiwan University, Taipei, Taiwan. (387-P29) Electrical Conduction Properties of Mg-doped C60 Films. Nobuaki Kojima, Masato Natori, Crisoforo Morales, Seiji Nishi, Masafumi Yamaguchi. Toyota Technological Institute, Nagoya, Japan.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


143


(388-P31) Growth Temperature Dependence of Structure in Mg-doped C60 Films. Seiji Nishi, Masato Natori, Nobuaki Kojima, Crisoforo Morales, Masafumi Yamaguchi. Toyota Technological Institute, Nagoya, Japan. (389-P33) Thin Film Encapsulation for Flexible Organic Solar Cells. Jongwoon Park, Cheolyoung Park, Jongho Lee, Giseok Heo, Taewon Kim, Gwangyoung Kim. Korea Institute of Industrial Technology, Gwangju, South Korea. (390-Q1) BIOPV. Ami Elazari. Millennium Electric T.O.U. Ltd., Raanana, Israel.

10:30 - 12:00 PM Kamehameha Exhibit Hall III.e

Area 8: Posters, PV Characterization: Materials and Devices

Chair(s): Steve Johnston, Jennifer Heath (391-S24) Novel Method and System for Monitoring CPV Cell and Module Temperature. Deborah A Adkins. The University of Nottingham, Nottingham, United Kingdom. (392-S26) Measurement of Strain Distribution in Multi-Crystalline Silicon Substrates for Solar Cells using Synchrotron Radiation. Koji Arafune, Shohei Miki, Masao Monden. University of Hyogo, Himeji, Japan. (393-S28) Application of Microwave Scanning Probes to Photovoltaic Materials. Kris A. Bertness, John B. Schlager, Norman A. Sanford, Atif Imtiaz, Thomas M. Wallis, Pavel Kabos. NIST, Boulder, CO, USA. (394-S30) Plasma Drift and Process Control in a VHF Plasma for Deposition of Microcrystalline Silicon Thin Film Solar Cells. Chia-Hao Chang1, Chih-Yung Huang1, Shih-Chin Lin1, Muh-Wang Liang1, Keh-Chyang Leou2. 1Industrial Technology Research Institute, Hsinchu, Taiwan, 2National Tsing Hua University, Hsinchu, Taiwan. (395-S32) A Fully Automated System For Local Spectral Characterization Of Photovoltaic Structures. Razvan Ciocan1, Zhuoyun Li1, Dae Han1, Domenic Assalone1, Fan Yang2, Wei Gao3, Eugenia Ciocan 4, Keith Emery5. 1Newport Corporation, Oriel Instruments, Stratford, CT, USA, 2Applied Materials, Inc., Santa Clara, CA, USA, 3Solasta Inc., Newton, MA, USA, 4Wentworth Institute of Technology, Boston, MA, USA, 5National Renewable Energy Laboratory, Golden, CO, USA. (396-S34) Optical Mapping of Large Area Thin Film Solar Cells. Zhiquan Huang1, Jie Chen1, Michelle N. Sestak1, Dinesh Attygalle1, Lila R Dahal1, Meghan R Mapes1, David A Strickler2, Kenneth R Kormanyos3, Robert W Collins1. 1Center for Photovoltaics Innovation and Commercialization, University of Toledo, Toledo, OH, USA, 2On-Line Coatings Technology, NSG-Pilkington, Northwood, OH, USA, 3Calyxo USA, Inc., Perrysburg, OH, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

144


(397-T2) Optical Metrology of Thin Film Solar Cells from 0.2 to 30 μm. Dinesh Attygalle, Zhiquan Huang, Prakash Koirala, Puruswottam Aryal, Michelle N. Sestak, Lila R Dahal, Meghan R Mapes, Robert W Collins. Center for Photovoltaics Innovation and Commercialization (PVIC), University of Toledo, Toledo, OH, USA. (398-T4) Direct Assessment of Series Resistance in Thin Film Solar Cells Utilizing Electroluminescence. Ayumi Tani, Takashi Fuyuki. Nara Institute of Science and Technology, Ikoma, Nara, Japan. (399-T6) Capacitance Analysis of Wire-Array Solar Cell. Oki Gunawan1, Babak Fallahazad2, Emanuel Tutuc2, Supratik Guha1. 1IBM T J Watson Research Center, Yorktown Heights, NY, USA, 2Dept. of Electrical and Computer Engineering, Univ. Texas at Austin, Austin, TX, USA. (400-T8) Recombination Activity Enhancement By Stress in Silicon. Paul Gundel, Martin C. Schubert, Friedemann D. Heinz, Wilhelm Warta. Fraunhofer ISE, Freiburg, Germany. (401-T10) Photoluminescence Imaging of Chromium in Crystalline Silicon. Holger Habenicht1, Martin, C. Schubert1, Gianluca Coletti2, Wilhelm Warta1. 1Fraunhofer Institute for Solar Energy Systems (ISE), Freiburg, Germany, 2Energy Research Centre of the Netherlands, Petten, Netherlands. (402-T12) High Throughput Hotspot Detection Using Time-Resolved Thermography. Gregory S. Horner, James E. Hudson, John M. Schmidt, Leonid A. Vasilyev, Gary Bultman. Tau Science Corporation, Mountain View, CA, USA. (403-T14) Characterization and Gauge Study of a High Speed Quantum Efficiency Apparatus. John M. Schmidt1, Leonid A. Vasilyev1, James E. Hudson1, Gregory S. Horner1, Ethan A. Good2, Maciej Dybiec2. 1Tau Science Corp., Mountain View, CA, USA, 2Solarworld Industries America, Hillsboro, OR, USA. (404-T16) Correlation of Dielectric and Vibrational Properties of Amorphous Hydrogenated Si for Photovoltaic Applications: Modeling and Experiment. Zahraa A. Ibrahim1,2, Anatoli I. Shkrebtii1, Franco Gaspari1, Timothy Teatro1. 1Faculty of Science, University of Ontario Institute of Technology, Oshawa, ON, Canada, 2Department of Physics, University of Toronto, Toronto, ON, Canada. (405-T18) High-resolution X-ray and Light Beam Induced Current (LBIC) Measurements of Multicrystalline Silicon Solar Cells. Gerald E Jellison1, John D Budai1, Charlee J C Bennett1, Chad E Duty1, Vijay Yelundur2, Ajeet Rohatgi2. 1Oak Ridge National Laboratory, Oak Ridge, TN, USA, 2Georgia Institute of Technology, Atlanta, GA, USA. (406-T20) AFM-Based Electrical Characterization of Laser Isolation and Back Surface Field in Multicrystalline Si Solar Cells. Chun-Sheng Jiang1, Helio R. Moutinho1, Yanfa Yan1, Mowafak M. Al-Jassim1, John Gorman2, Alain Blosse2. 1National Renewable Energy Laboratory, Golden, CO, USA, 2CaliSolar Inc., Sunnyvale, CA, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


145


(407-T22) Application of Imaging Techniques to Si, Cu(In,Ga)Se2, and CdTe and Correlation to Solar Cell Parameters. Steven W. Johnston, Ingrid L. Repins, Nathan J. Call, Rajalakshmi Sundaramoorthy, Kim M. Jones, Bobby To. National Renewable Energy Laboratory, Golden, CO, USA. (408-T24) Characterization of Defects in Photovoltaics using Thermoreflectance and Electroluminescence Imaging. Dustin Kendig, Glenn Alers, Ali Shakouri. University of California, Santa Cruz, CA, USA. (409-T26) Evaluation of Emitter Profiles and Lateral Uniformity on Crystalline Silicon Photovoltaic Cells Using Scanning Capacitance Microscopy. Laura L. Kosbar, George G. Totir, Jakub W. Nalaskowski, Kathryn C. Fisher, Lukasz J. Hupka. IBM T.J. Watson Research Center, Yorktown Heights, NY, USA. (410-T28) Measurement of the Sodium Concentration in CIGS Solar Cells via Laser Induced Breakdown Spectroscopy. Jeremy M. D. Kowalczyk1, Jeffrey Perkins2, Jess Kaneshiro1, Nicolas Gaillard1, Yuancheng Chang1, Alexander DeAngelis1, Stewart A. Mallory1, Eric Miller1. 1Hawai’i Natural Energy Institute, University of Hawai’i Manoa, Honolulu, HI, USA, 2Hawai’i Institute of Geophysics, University of Hawai’i Manoa, Honolulu, HI, USA. (411-T30) A Method to Determine the Absorbtance of Thin Films for Photovoltaic Technology. John H. Lehman1, Nathan Tomlin1, Katherine E. Hurst2, D.B. Tanner3, Kati Kamaras4, Aron Pekker4. 1National Institute of Standards and Tehcnology, Boulder, CO, USA, 2National Renewable Energy Laboratory, Golden, CO, USA, 3Univeristy of Florida, Gainesville, FL, USA, 4Hungarian Academy of Sciences, Budapest, Hungary. (412-T32) Coordinated Electrical Characterization System for Photovoltaic Devices. Jian V. Li, Jerry Tynan, Steve W. Johnston, Hao-Chih Yuan, Qi Wang, David S. Albin, Xiaonan Li, Dean H. Levi. National Renewable Energy Laboratory, Golden, CO, USA. (413-T34) Applications of Scanning Electron Microscopy for Characterization of Radiation Effects in Multijunction Solar Cells. Serguei I. Maximenko1, Scott R. Messenger2, Cory D. Cress2, Jeffrey H. Warner2, Maria Gonzalez1, Jamie T. Freitas2, Robert J. Walters2. 1Global Defense Technology & Systems, Inc.,, Crofton, MD, USA, 2US Naval Research Laboratory, Washington, DC, USA. (414-U2) The Morphological of MEH-PPV Films and Its Application for Hybrid Solar Cell. Quynh Nhu Nguyen Truong, Jae Hak Jung. Yeungnam University, Daegu, Korea. (415-U4) Raman Scattering Process Monitoring of Thin Film Chalcopyrite Technologies: Application for in-situ Control of Composition of Precursors in Electrodeposited CuIn(S,Se)2 Solar Cells. Victor Izquierdo-Roca1, Edgardo Saucedo2, Jesús S. Jaime-Ferrer3, Xavier Fontane2, Alejandro Perez-Rodriguez1, 2, Veronica Bermudez3, Joan R. Morante1, 2. 1M-2E/XaRMAE/IN2UB, Departament d’Electronica, Universitat de Barcelona, Barcelona, Spain, 2IREC, Catalonia Institute for Energy Research, Barcelona, Spain, 3NEXCIS, Rousset, France.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

146


(416-U6) Application of X-Ray Computed Tomography in Silicon Solar Cells. V.A. Popovich1, M. Janssen1, W. Verwaal2, I.J. Bennett3, I.M. Richardson1. 1Delft University of Technology, Department of Materials Science & Engineering, Delft, Netherlands, 2Delft University of Technology, Faculty of Geo-Engineering, Department of Geotechnology, Delft, Netherlands, 3Energy Research Centre of the Netherlands, Solar Energy, PV Module Technology, Petten, Netherlands. (417-U8) PV Module Defect Detection by Combination of Mechanical and Electrical Analysis Methods. Martin Sander1, Bastian Henke1,2, Stefan Schweizer1,2, Matthias Ebert1, Jörg Bagdahn1. 1Fraunhofer Center for Silicon Photovoltaics, Halle, Germany, 2Centre for Innovation Competence SiLi-nano®, Martin Luther University of Halle-Wittenberg, Halle, Germany. (418-U10) Future of Raman in PV Development. George Sarau1, Silke Christiansen1,2, Renata Lewandowska3, Bernard Roussel3. 1Institute of Photonic Technology, Jena, Germany, 2Max Planck Institute for the Science of Light, Erlangen, Germany, 3HORIBA Jobin Yvon S.A.S., Villeneuve d’Ascq, France. (419-U12) High Resolution Inline Detection of Changes in the Conduction Type of Multicrystalline Silicon Bricks by Contactless Photoconductivity Measurements. N Schüler, D Mittelstrass, K Dornich, J R Niklas. Freiberg Instruments GmbH, Am St. Niclas Schacht 13, Freiberg, Germany. (420-U13) Transient Absorption for Characterization of Intermediate Band Solar Cells. Steve Smith. SDSM&T, Rapid City, SD, USA. (421-U14) Electroluminescence Imaging of III-V Multijunction Cells. Claus G. Zimmermann. EADS Astrium, Munich, Germany.

3:30 - 5:00 PM Kamehameha Exhibit Hall III.a

Area 1: Posters, Fundamentals & New Concepts: Nanostructures

Chair(s): Ryne Raffaelle, Yoshitaka Okada, Nicholas Ekins-Daukes (422-A1) Fabrication of Al-doped Zinc Oxide Top Contact for Radial p-n Junction based Silicon Solar Cell. Seong-Ho Baek, Jae Hyun Kim. DGIST, Daegu, Korea. (423-A4) Monolithic III-V Nanowire PV for Photoelectrochemical Hydrogen Generation. Xin-Yu Bao1, Blaise A. Pinaud2, Jason Parker1, Shaul Aloni3, Thomas F. Jaramillo2, H.-S. Philip Wong1. 1Department of Electrical Engineering, Stanford University, Stanford, CA, USA, 2Department of Chemical Engineering, Stanford University, Stanford, CA, USA, 3The Molecular Foundry, Lawrence Berkeley National Laboratory, Berkeley, CA, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


147


(424-A7) InAs/GaAs Strain Coupled Multilayer Quantum Dots with InAlGaAs Quaternary Capping Layer for Photovoltaic Applications. Sauvik Chowdhury, Nilanjan Halder, Sourav Adhikary, Subhananda Chakrabarti. Indian Institute of Technology Bombay, Mumbai, India. (425-A10) Absorption Coefficients of Quantum Dot Intermediate Band Materials With Negligible Valence Band Offset. Som Dahal, Keun-Yong Ban, Christiana Honsberg. Arizona State University, Tempe, AZ, USA. (426-A13) Numerical Modeling of Hot Electron GaAs/AlxGa1-xAs Quantum Well Photovoltaic. Hamid Z. Fardi. Univeristy of Colorado Denver, Denver, CO, USA. (427-A16) Substrate Orientation Effects on Quantum Dot Enhanced GaAs Solar Cells. David V Forbes1, Chris G Bailey1, Stephen Polly1, Chelsea R Plourde1, Seth M Hubbard1, Ryne P Raffaelle2. 1Rochester Institute of Technology, Rochester, NY, USA, 2National Renewable Energy Laboratory, Golden, CO, USA. (428-A19) Energy Band Structure Design for Quantum-Dot, Intermediate-Band Solar Cells. Weiguo Hu1, Tomoya Inoue2, Takashi Kita1,2, Osamu Kojima1,2, Osamu Wada1,2. 1CREATE, Kobe University, Kobe, Japan, 2Graduate School of Engineering, Kobe University, Kobe, Japan. (429-A22) Flexible Engineering of Nanotube Arrays in Morphology and Materials. Zhifeng Huang1, Kenneth D. Harris2, Michael J. Brett2,3. 1Hong Kong Baptist University, Kowloon Tong, Hong Kong, 2NINT, Edmonton, AB, Canada, 3University of Alberta, Edmonton, AB, Canada. (430-A29) Analysis and Fabrication of Submicron PbTe/ZnTe Thin Films for Superlattice Structured Solar Cells. Pritpal Singh, Amal Kabalan, Sukriti Jain. Villanova University, Villlanova, PA, USA. (431-A32) Nanostructured ZnO and TiO2 Solar Cells using CdS as a Sensitizer. Bo Wang, Lei Kerr. Dept. of Paper and Chemical Engineering, Miami University, Oxford, OH, USA. (432-B1) Intraband Relaxation of Photoexcited Carriers In Multiple Stacked Quantum Dots and Quantum Dot Chains. Osamu Kojima1, Masataka Mamizuka1, Takashi Kita1, Osamu Wada1, Kouichi Akahane2. 1Kobe University, Kobe, Japan, 2National Institute of Information and Communications Technology, Tokyo, Japan. (433-B4) Silicon Quantum Dot Optical Properties and Synthesis: Implications for Photovoltaic Devices. Benjamin G Lee1, Bhavin N Jariwala2, Reuben T Collins3, Sumit Agarwal2, Paul Stradins1. 1National Center for Photovoltaics, National Renewable Energy Lab, Golden, CO, USA, 2Department of Chemical Engineering, Colorado School of Mines, Golden, CO, USA, 3Department of Physics, Colorado School of Mines, Golden, CO, USA. (434-B7) ZnO-ZnTe Nanocone Heterojunctions for Efficient Carrier Transport for Photovoltaic Conversion. Sang Hyun Lee, Xiaoguang Zhang, Barton Smith, Jun Xu. Oak Ridge National Laboratory, Oak Ridge, TN, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

148


(435-B10) Multi-Stacked InAs/GaNAs Quantum Dots with Direct Si Doping for use in Intermediate-Band Solar Cells. Takayuki Morioka1,2, Ryuji Oshima1,2, Ayami Takata1,2, Yasushi Shoji2,3, Tomoya Inoue4, Takashi Kita4, Yoshitaka Okada1,2. 1The University of Tokyo, School of Engineering, Tokyo, Japan, 2The University of Tokyo, Research Center for Advanced Science and Technology, Tokyo, Japan, 3University of Tsukuba, Ibaraki, Japan, 4Kobe University, Graduate school of Engineering, Kobe, Japan. (436-B13) Numerical Modeling of InGaAs Quantum Dot Intermediate Band Multistacked Solar Cells. B Muralibabu1, Madheswaran Muthusamy2. 1Paavai Engineering College, Namakkal, India, 2Muthyammal Engineering College, Rasipuram, India. (437-B16) Study on Spectral Response of Schottky-Type Multi-Stack High Density Quantum Dot Molecule Photovoltaic Cells at Concentrated Light. Ong-arj Tangmettajittakul, Supachok Thainoi, Pornchai Changmoang, Songphol Kanjanachuchai, Somchai Rattanathammaphan, Somsak Panyakeow. Chulalongkorn Univewrsity, Bangkok, Thailand. (438-B19) Computation of Resonant Atomic Vibrations in Core-Shell Quantum Dot Superlattices and Mixed-Phase Nano-Porous Systems for the Hot Carrier Solar Cell Light Absorber Material. Robert J Patterson, Binesh P Veettil, Dirk Konig, Martin A Green, Gavin Conibeer. University of New South Wales, Sydney, Australia. (439-B22) Disorder and Faceting in Nanowire Solar Cell Arrays. Evan R Pickett1, Erik Garnett1, Michael D McGehee1, James S Harris, Jr.2. 1Materials Science, Stanford, CA, USA, 2Electrical Engineering, Stanford, CA, USA. (440-B29) Fluorescent Manganese-Doped Zinc Sulphide Nanoparticles for Spectral Shifting. Suranjan Sen1, Pratibha Sharma1, Chetan Singh Solanki1, Rajdip Bandyopadhyaya2. 1Department of Energy Science and Engineering, IIT Bombay, Powai, Mumbai, India, 2Department of Chemical Engineering, IIT Bombay, Powai, Mumbai, India. (441-B32) Multi-Stacked InGaAs/GaNAs Quantum Dot Solar Cell Fabricated on GaAs (311)B Substrate. Yasushi Shoji1,2, Ryuji Oshima2,3, Ayami Takata2,3, Takayuki Morioka2,3, Yoshitaka Okada2,3. 1University of Tsukuba, Institute of Applied Physics, Ibaraki, Japan, 2The University of Tokyo, Research Center for Advanced Science and Technology (RCAST), Tokyo, Japan, 3The University of Tokyo, Graduate School of Engineering, Tokyo, Japan. (442-C1) Characteristics of Highly Stacked Quantum Dot Solar Cells Fabricated by Intermittent Deposition of InGaAs. Takeyoshi Sugaya1, Shigenori Furue1, Osamu Numakami1, 2, Takeru Amano1, Masahiko Mori1, Kazuhiro Komori1, Yoshinobu Okano2, Shigeru Niki1. 1National Institute of Advanced Industrial Science and Technology (AIST), Tsukuba, Japan, 2Tokyo City University, Tokyo, Japan. (443-C4) Towards Silicon Nanocrystals Based Solar Cells: Morphological Properties and Conduction Phenomena. Kavita Surana1, Hadrien Lepage1, Daniel Bellet2, Gilles Le Carval1, Mathieu Baudrit3, Philippe Thony3, Pierre Mur1. 1CEA-LETI-Minatec, Grenoble, France, 2INPG-Laboratoire des Matériaux et du Génie Physique (LMGP), Grenoble, France, 3CEA-LITEN-Institut National de l’Energie Solaire (INES), Le Bourget de Lac, France.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


149


(444-C7) Enhanced Photovoltaic Effect of Nanosecond-Laser Processed Silicon Nanocrystals Embedded into TiO2 Nanotubes. Vladimir Svrcek, Ivan Turkevych,, Koujiro Hara, Michio Kondo. Research Center for Photovoltaics, National Institute of Advanced Industrial Science and Technology (AIST), Central 2, Umezono 1-1-1,, Tsukuba, Japan. (445-C10) Fabrication of 100 Layer-Stacked InAs/GaNAs Strain-Compensated Quantum Dots on GaAs(001) for Application to Intermediate Band Solar Cells. Ayami Takata1,2,4, Ryuji Oshima1,2, Yasushi Shoji2,3, Kouichi Akahane2,4, Yoshitaka Okada1,2. 1School of Engineering, The University of Tokyo, Tokyo, Japan, 2Research Center for Advanced Science and Technology, The University of Tokyo, Tokyo, Japan, 3Institute of Applied Physics, University of Tsukuba, Ibaraki, Japan, 4National Institute of Information and Communications Technology, Tokyo, Japan. (446-C12) High S/N Crystallinity Measurement and Effective Defect Passivation in Silicon Nanostructures for Third Generation Photovoltaics. Keiji Watanabe, Toshiyuki Mine, Ryuta Tsuchiya, Mutsuko Hatano. Central Research Laboratory, Hitachi, Ltd., Tokyo, Japan. (447-C14) Stacking Growth of In-Plane InAs Quantum-Dot Superlattices on GaAsSb/GaAs(001) for Solar Cell Applications. Toshihiko Inaji, Jun Ohta, Koichi Yamaguchi. University of Electro-Communications, Tokyo, Japan. (448-C16) Photovoltaic Effect in Ge Nanocrystals/c-Silicon Heterojunctions Devices. Yao Yao, Bo Zhang, Martin A. Green, Gavin Conibeer, Santosh Shrestha. ARC Photovoltaics Centre of Excellence, University of New South Wales, Sydney, Australia.


Area 2: Posters, CIGS & CdTe: CdTe and Other Materials

Chair(s): Ayodhya Tiwari, Tim Gessert (449-C21) Band Gap Determination of Cu2ZnSnSe4 Thin-Films. Sejin Ahn, Sunghun Jung, Jihye Gwak, Ara Cho, Keesik Shin, Kyunghoon Yoon, JaeHo Yun. Korea Institute of Energy Research, Daejeon, Korea. (450-C24) Sputter Deposited ZnTe/ZnSe/ZnO Heterojunctions for Photovoltaic Applications. Okechukwu Akpa1, Shaik Shoieb1, Trenton Thompson1, Tamara Isaacs-Smith2, Philip Anderson3, Supapan Seraphin3, Kalyan Das1. 1Tuskegee University, Tuskegee, AL, USA, 2Auburn University, Auburn, AL, USA, 3University of Arizona, Tucson, AZ, USA. (451-C27) Inexpensive, Abundant, Non-toxic Thin Films for Solar Cell Applications Grown by Reactive Sputtering. Vardaan Chawla, Stacey Bent, Bruce Clemens. Stanford University, Stanford, CA, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

150


(452-C30) Sulfurization Studies of The Potential Thin Film Solar Absorber Cu2ZnSnS4. An-Jen Cheng1, Stephen A. Campbell1, Eray Aydil 2, Chris Leighton2, Mike Manno2, Rachel Hoffman3, Rachel Frakie2. 1Dept. of Electrical and Computer Engineering, University of Minnesota, Minneapolis, MN, USA, 2Dept. of Chemical Engineering and Material Science Engineering, University of Minnesota, Minneapolis, MN, USA, 3Dept. of Chemical Engineering, Ithaca, NY, USA. (453-C33) Working Quantum Efficiency of CdTe Solar Cell. Z. Cheng1, K. Lo2, D. Chen1, T. Zhou2, Q. Wang3, G.E. Georgiou1, K.K Chin1. 1Department of Physics, Apollo CdTe Solar Energy Center (pending), NJIT, Newark, NJ, USA, 2Department of Physcis, NJIT, Newark, NJ, USA, 3National Renewable Energy Laboratory (NREL), Golden, CO, USA. (454-D2) The Roles of Cu Impurity States in CdTe Thin Film Solar Cells. Ken K. Chin1, Tim Gessert2, Suhuai Wei2. 1Dept. of Physics and Apollo CdTe Solar Energy Research Center, NJIT, Newark, NJ, USA, 2National Renewable Energy Laboratory, Golden, CO, USA. (455-D5) Effects of Substrate Temperature on the Properties of Cu2ZnSnSe4 Thin Film Solar Cells Fabricated via One-Step Co-Evaporation Process. Jae Ho Yun, Sunghun Jung, Jihye Gwak, Sejin Ahn, Ara Cho, Kyunghoon Yoon. Photovoltaic Research Center, Korea Institute of Energy Research (KIER), Daejeon, Korea. (456-D8) In-Situ XRD Investigation on Phase Transition of CdTe Thin Films during a CdCl2 Heat Treatment. MaengJun Kim1, SungHo Lee2, SangHo Sohn1. 1KyungPook National University, Daegu, South Korea, 2Nano Practical Application Center, Daegu, South Korea. (457-D11) Infrared PL Studies of Sputtered CdTe Films and Cells. DoHyoung Kwon, Naba R. Paudel, Xiangxin Liu, Kristopher A. Wieland, Alvin D. Compaan. Dept. of Physics and Astronomy, The University of Toledo, Toledo, OH, USA. (458-D14) Comparative Study of CdTe Thin Film Solar Cells with Wet and Dry CdCl2 Treatment Process. Jaehyung Lee1, Hyunmin Ryu1, Gayeon Lee1, Donggun Lim2, Keajoon Yang2, Wonseok Choi3, Junsin Yi4. 1Kunsan National University, Kunsan, Korea, 2Chungju National University, Chungju, Korea, 3Hanbat National University, Daejeon, Korea, 4Sungkyunkwan University, Suwon, Korea. (459-D17) The Effects of High Resistance Buffer Oxides on the Performance of CdTe Thin Film Solar Cells Grown on Commercially Available TCO Coated Glass. Craig M Lennon, Philip F Bechmann, Jon Ellsworth, Paul Boieriu, Joe Margetis, Tomasz Biegala, Dong Xu, Michael Carmody, Ramesh Dhere. EPIR Technologies, Inc., Bolingbrook, IL, USA. (460-D20) Material Property Studies of Cadmium Tin Oxide Thin Films Prepared by Linear Combinatorial Synthesis . Xiaonan Li, Gessert A. Timothy. National Renewable Energy Laboratory, Golden, CO, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


151


(461-D23) Interface Analysis in CdTe/CdS Solar Cells. Bogdan Lita1, Katharine Dovidenko2, Shubhra Bansal2, Vincent S Smentkowski2, Laurie E Le Tarte2, Hong Piao2, Matthew Young3. 1PrimeStar Solar, Arvada, CO, USA, 2GE Global Research Center, Niskayuna, NY, USA, 3National Renewable Energy Laboratory, Golden, CO, USA. (462-D26) A Revised Version of the AMPS Simulation Code. Yiming Liu1, Dan Heinzel2, Angus Rockett2. 1Institute of Photo-Electronic Thin Film Devices and Technology,Nankai University, Tianjin, China, 2Department of Materials Science and Engineering, University of Illinois, Urbana, IL, USA. (463-D29) Fundamental Study of CSTS Absorber Layers for Economical and Environmentally-Benign Thin Film Photovoltaics. Elizabeth A Lund1, Jeffrey L Johnson2, Haritha Nukala3, Win Maw Hlaing Oo2, Michael A Scarpulla2,3. 1University of Utah Department of Chemical Engineering, Salt Lake City, UT, USA, 2University of Utah Department of Electrical and Computer Engineering, Salt Lake City, UT, USA, 3University of Utah Department of Material Science and Engineering, Salt Lake City, UT, USA. (464-D32) Effect of Chemical Treatment on the Optical Properties of a Cadmium Telluride Photovoltaic Device Investigated by Spectroscopic Ellipsometry. Sandeep Kohli1, Venkatesan Manivannan2, James Hilfiker3, Patrick McCurdy1, Robert Enzenroth2, Kurt Barth2, Scott Smith2, Rick Leubs2, Jason Kephart2, Walajabad Sampath2. 1Department of Chemistry, Colorado State University, Fort Collins, CO, USA, 2Department of Mechanical Engineering, Colorado State Universtiy, Fort Collins, CO, USA, 3J.A. Woollam Inc, Lincoln, NE, USA. (465-E1) 2SSS Pathways to Fabrication of Kesterite Solar Cells. Don L Morel, Chris S Ferekides, Satya K Bendapudi. University of South Florida, Tampa, FL, USA. (466-E4) Electrical Properties of CdTe/CdS and CdTe/SnO2 Devices Studied with Scanning Kelvin Probe Microscopy. Helio R. Moutinho, Ramesh G., Dhere, Chun-Sheng Jiang, David S. Albin, Mowafak M. Al-Jassim. National Renewable Energy Laboratory, Golden, CO, USA. (467-E7) Structural Properties of CdTe Thin Films for Solar Cell Applications Deposited on Flexible Foil Substrates. Vasilios Palekis, Dongna Shen, Shweta Bhandaru, Elias Stefananakos, Don L. Morel, Chris Ferekides. University Of South Florida, Tampa, FL, USA. (468-E10) Ultrasonic Spray Pyrolysis of CZTS Solar Cell Absorber Layers and Characterization Studies. Tejas Prabhakar, Nagaraju J. Indian Institute of Science, Bangalore. 560012, India. (469-E13) Is a CdCl2 Treatment Necessary for Thin-Film CdS-CdTe Solar Cells? Takhir Razykov1, Nowshad Amin2, Gerardo Contreras-Puente3, Bobur Ergashev1, Chris Ferekides4, Yogi Goswami4, Maruf Hakkulov1, Ahror Hubbimov1, Sergio Jimenez-Sandoval5, Kudrat Kouchkarov1, Kamaruzzaman Sopian2, Harin Ullal6, Hari Upadhyaya7. 1Physical-Technical Institute, Tashkent, Uzbekistan, 2UKM, Bangi, Malaysia, 3IPN, Mexico City, Mexico, 4USF, Tampa, FL, USA, 5CINVESTAV, Queretaro, Mexico, 6NREL, Golden, CO, USA, 7CREST, Loughboro, United Kingdom.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

152


(470-E16) Temperature Dependent Charge Transport of Spin-Cast CdTe Nanoparticle Solar Cells. Yvonne W. Rodriguez, Jeremy P. Olson, Ingrid E. Anderson, Sue A. Carter. University of California, Santa Cruz, Santa Cruz, CA, USA. (471-E19) Optical Properties of CdS Thin Films Obtained by CSVT under Different Growth Conditions and their Influence in Prototype PV Devices. Jorge Sastré-Hernández1,2, Gerardo Contreras-Puente1, Rogelio Mendoza-Pérez3, Jorge Aguilar-Hernández1, Gerardo Ortega-Cervantes1, Osvaldo Vigil-Galán1, Wilder Chicana-Nuncebay2, L Znaidi4. 1Escuela Superior de Física y Matemáticas – I.P.N. Edificio No. 9 U.P.A.L.M., Col. Lindavista, C.P.07738, México D.F., Mexico, 2PLEE - IPN U.P.A.L.M Av. Wilfrido Massieu s/n, Col. Lindavista, C.P. 07738, México D.F., Mexico, 3Universidad Autónoma de la Ciudad de México, Av. Prolongación San Isidro Núm. 151, Col. San Lorenzo Tezonco, C.P. 09790, México D.F., Mexico, 4High Pressures and Engineering Materials Laboratory (LIMHP) - CNRS, Galilee Institut, University of Paris XIII, Av. Jean Baptist 99, 93430, Villetaneause, France, France. (472-E22) Tellurides as Back Contacts for Substrate CdTe Thin Film Solar Cells on Flexible Foil Substrates. Dongna Shen, Vasilios Palekis, Shweta Bhandaru, Deidra Hodges, Vasudha Guntur, Lee Stefanakos, Don Morel, Chris Ferekides. Department of Electrical Engineering, University of South Florida, Tampa, FL, USA. (473-E25) Growth of High Quality Cu2ZnSnS4 Thin Films by Co-evaporation. Charles Surya, Hardy H. Lui, Kelvin K. Leung, Patrick W. Fong. The Hong Kong Polytechnic University, Department of Electronic and Information Engineering, Hong Kong, Hong Kong. (474-E28) Chemical Etching of Cu2ZnSn(S,Se)4 Monograin Powder. Kristi Timmo, Mare Altosaar, Jaan Raudoja, Maarja Grossberg, Mati Danilson, Tiit Varema, Enn Mellikov. Tallinn University of Technology, Tallinn, Estonia. (475-E31) Radiative Recombination Levels in ZnO/CdS/CdTe Structures. Sergiu A. Vatavu1, Vladimir M. Fedorov1, Corneliu Gh. Rotaru1, Petru I. Chetrus1, Roman I. Scurtu1, Ion Gh. Inculet1, Petru A. Gasin1, Marin I. Rusu2, Martha Ch. Lux-Steiner2. 1Faculty of Physics, Moldova State University, 60 A. Mateevici str., MD 2009, Chisinau, Moldova, 2Solar Energy Research, Helmholtz-Zentrum Berlin für Materialien und Energie, Lise-Meitner Campus, Hahn-Meitner-Platz 1, 14109, Berlin, Germany. (476-E34) PL Investigations of the CdS/CdTe Heterojunctions in Superstrate Configuration. Sergiu A. Vatavu1, Deidra Hodges2, Vassilios Palekis2, Shweta Bhandaru2, Arcadi B. Chirita1, Iuliana M. Caraman3, Petru A. Gasin1, Don L. Morel2, Chris S. Ferekides2. 1Faculty of Physics, Moldova State University, 60 A. Mateevici str., Chisinau, MD 2009, Chisinau, Moldova, 2Center for Clean Energy and Vehicles, Department of Electrical Engineering, University of South Florida, 33620, Tampa, FL, USA, 3Engineering Department, University of Bacau, 157 Calea Marasesti, 600115, Bacau, Rumania. (477-F3) A Chemical Bath Process for Depositing Cu2ZnSnS4 Photovoltaic Absorbers. Artit Wangperawong, Jeffrey S. King, Steven M. Herron, Benjamin P. Tran, Kristine Pangan-Okimoto, Stacey F. Bent. Stanford University, Stanford, CA, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


153


(478-F6) Modeling of CdZnTe (CdSe) and CIGS and Tandem Solar Cells. Yegao Xiao, Zhiqiang Li, Michel Lestrade, Zhanming S. Li. Crosslight Software Inc, Burnaby, BC, Canada.


Area 3: Posters, III-V’s & Concentrators: III-V Concentrator Cells

Chair(s): J. Ermer, W. Guter (479-F18) Qualification Testing of 40% Metamorphic CPV Solar Cells. Omar Al Taher, Robert Cravens, Peichen Pien, Russ Jones, Pete Hebert, Jazper Chin, Jim Ermer. Spectrolab Inc, Sylmar, CA, USA. (480-F20) Traps in AlGaInP Materials and Devices Lattice Matched to GaAs for Multi-junction Solar Cells. Aaron R Arehart, Mark R Brenner, Zeng Zhang, Krishna Swaminathan, Steve A Ringel. Dept. of Electrical and Computer Engineering The Ohio State University, Columbus, OH, USA. (481-F22) A New Circular Contact Grid Pattern, Designed for Solar Cells in a Mechanical Stack. Günther M.M.W. Bissels, Matthieu A.H. Asselbergs, Erik J. Haverkamp, Niek J. Smeenk, John J. Schermer. IMM, Radboud University Nijmegen, Nijmegen, Netherlands. (482-F24) AlSb Intrinsic Absorber Layer in p – i – n Junction Solar Cells. Rabin Dhakal1, Yung Huh2, Sandeep K Patel2, David Galipeau1, Xingzhong Yan1. 1Department of Electrical Engineering & Computer Science, South Dakota State University, Brookings, 57007, SD, USA, 2Department of Physics, South Dakota State University, Brookings, 57007, SD, USA. (483-F26) Fast Growth Rate GaAs and InGaP for Triple Junction Solar Cells. Chris W Ebert, Rudy. Parekh, Ziggy Pulwin, Wei Zhang, Dong Lee, Daniel Byrnes. Veeco Turbodisk, Somerset, NJ, USA. (484-F28) Tandem Solar Cells Involving III-V and IV Semiconductor Junctions. Mahieddine Emziane. Masdar Institute, Abu Dhabi, United Arab Emirates. (485-F30) Theoretical Simulations of the Performance of p-i-n InGaN Single Homo-junction Solar Cells. Shih-Wei Feng1, Yu-Ru Su1, Chih-Ming Lai2, P. H. Tseng3, Y. S. Chen3, L. W. Tu3, M. C. Chou4, C. H. Chen5, W. C. Sun5. 1Department of Applied Physics, National University of Kaohsiung, Kaohsiung, Taiwan, 2Department of Electronic Engineering, Ming Chuan University, Taoyuan, Taiwan, 3Department of Physics and Center for Nanoscience and Nanotechnology, Kaohsiung, Taiwan, 4Department of Materials Science & Opto-electronic Engineering, National Sun Yat-Sen University, Kaohsiung, Taiwan, 5Photovoltaics Technology Center, Industrial Technology Research Institute, Hsinchu, Taiwan.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

154


(486-F32) Oxidation and Characterization of AlInP under Light-Soaked, Damp Heat Conditions. Ryan M France, Myles A Steiner, Todd G Deutsch, Eric A Brucker, Chun-Sheng Jiang, Andrew G Norman. National Renewable Energy Laboratory, Golden, CO, USA. (487-F34) Cell-Level Thermal Management Issues in Concentrator III-V Multijunction Solar Cells. John F. Geisz, Daniel J. Friedman, Sarah R. Kurtz, Myles A. Steiner, William E. McMahon, Lynn Gedvilas, Anna Duda, Michelle Young, Waldo Olavarria. National Renewable Energy Laboratory, Golden, CO, USA. (488-G2) Defect States with an Occupation-Dependent Lattice Configuration in Zinc-Doped Ga0.58In0.42P on GaAs. Timothy H. Gfroerer1, Daniel G. Hampton1, Mark W. Wanlass2. 1Davidson College, Davidson, NC, USA, 2NREL, Golden, CO, USA. (489-G4) GaAsP/Si Solar Cells and Metamorphic, High Bandgap Ga-rich InGaP on GaAsP/Si for Ideal Multijunctions on Si. Tyler J Grassman, Andrew M Carlin, Steven A Ringel. Dept. of Electrical and Computer Engineering, The Ohio State University, Columbus, OH, USA. (490-G6) Design and Growth of III-V Nanowire Solar Cell Arrays on Low Cost Substrates. Anjia Gu1, Yijie Huo2, Shu Hu3, Shruti Thombare3, Evan Pickett3, Tomas Sarmiento2, Dong Liang4, Shuang Li4, Angie Lin3, Zongfu Yu1, Jingzhou Yan5, Majid Riazia5, Shanhui Fan2, Paul McIntyre3, Yi Cui3, James Harris2,1,3. 1Department of Applied Physics, Stanford University, Stanford, CA, USA, 2Department of Electrical Engineering, Stanford University, Stanford, CA, USA, 3Materials Science and Engineering, Stanford University, Stanford, CA, USA, 4Department of Physics, Stanford University, Stanford, CA, USA, 5OEpic Semiconductors Inc., Sunnyvale, CA, USA. (491-G8) Analysis of 2- and 3-Terminal GaInP/GaAs Concentrator Cells for Maximum Daily, Monthly, and Yearly Energy Output. Alexander W Haas, John R Wilcox, Jeffery L Gray, Richard J Schwartz. Purdue University, West Lafayette, IN, USA. (492-G10) Numerical Analysis of a Distributed Emitter Model. Alexander W Haas, John R Wilcox, Jeffery L Gray, Richard J Schwartz. Purdue University, West Lafayette, IN, USA. (493-G12) Enhanced N Incorporation and Improved Optical Properties in GaAsN Epilayers by using High-Index GaAs Substrates. Xiuxun Han, Hidetoshi Suzuki, Jong-Han Lee, Makoto Inagaki, Nobuaki Kojima, Yoshio Ohshita, Masafumi Yamaguchi. Toyota Technological Institute, Nagoya, Japan. (494-G14) Improvement of Minority Carrier Lifetime in GaAsN Grown by Chemical Beam Epitaxy. Takahiko Honda, Makoto Inagaki, Hidetoshi Suzuki, Nobuaki Kojima, Yoshio Ohshita, Masafumi Yamaguchi. Toyota Technological Institute, Nagoya, Japan. (495-G16) Effect of Cell Size on GaAs Concentrators with InAs Quantum Dots. Stephen Polly, Michael Harris, Zac Bittner, Christopher Bailey, David Forbes, Seth Hubbard. Rochester Institute of Technology, Rochester, NY, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


155


(496-G18) Origin of Near-Band-Edge Luminescence of GaAsN. Makoto Inagaki, Hidetoshi Suzuki, Nobuaki Kojima, Yoshio Ohshita, Masafumi Yamaguchi. Toyota Technological Institute, 2-12-1 Hisakata, Tempaku, Nagoya 468-8511, Japan. (497-G20) 29.9% High-Efficiency GaInP2/GaAs/Ge Triple Cells in China. Jianwen Xu, Depeng Jiang, Jianfeng Lu, Weiying Chi, Mnegyan Zhang, Liangxing Wang, Wei Zhang. Shanghai Institute of Space Power Sources, Shanghai, China. (498-G22) Numerical Simulations of Triple-Junction GaInP/GaAs/Ge Solar Cells to Provide Insight into Fill-Factor Losses at High Concentration. Ana Kanevce1,2, Wyatt K. Metzger1,3. 1National Renewable Energy Laboratory, Golden, CO, USA, 2Colorado State University, Fort Collins, CO, USA, 3Primestar Solar, Arvada, CO, USA. (499-G24) Formation of GaAs Buffer by the Variation of the Flow Rate of Source for GaAs Seed on Si Substrate. Hyo Jin Kim, Sou Young Yu, Hang Ju Ko, Seong Min Kim, Seon Hoon Kim, Doo Gun Kim, Hyun Chul Ki, Myung Soo Han. Optoelectronic Device Team, Korea Photonics Technology Institute, Wolchul-dong 971-35, Buk-gu, Gwangju 500-460, Korea. (500-G26) Investigation of Surface Passivation on GaAs-based Compound Solar Cell Using Photoelectrochemical Oxidation Method. Chun-Yen Tseng1, Chih-Hung Wu2, Hwa-Yuh Shin2, Ching-Ting Lee1. 1Institute of Microelectronics, Department of Electrical Engineering National Cheng Kung University, Tainan, Taiwan, Republic of China, Tainan, Taiwan, 2Institute of Nuclear Energy Research Atomic Energy Council, Taoyuan, Taiwan, Republic of China, Taoyuan, Taiwan. (501-G28) Low Temperature Growth GaAs on Ge by Chemical Beam Epitaxy. Jong-Han Lee, Hidetoshi Suzuki, Xiuxun Han, Makoto Inagaki, Kazuma Ikeda, Nobuaki Kojima, Yoshio Ohshita, Masafumi Yamaguchi. Toyota Technological Institute, Nagoya, Japan. (502-G30) Improved Contact Design Methodology for Solar Cells. Jing-Jing Li, Ding Ding, Swee Hoe Lim, Yong-Hang Zhang. Arizona State University, Tempe, AZ, USA. (503-G32) Wide Band Gap Gallium Phosphide (GaP) Solar Cells for Multi-Junction Solar Cell System. Xuesong Lu1, Susan Huang2, Robert Opila2, Allen Barnett1. 1University of Delaware, Electrical and Computer Engineering Department, Newark, DE, USA, 2University of Delaware, Materials Science and Engineering Department, Newark, DE, USA. (504-G34) Antimony Enhanced Homogeneous Nitrogen Incorporation into GaInNAs Films Grown by Atomic Hydrogen-assisted Molecular Beam Epitaxy. Naoya Miyashita1,2, Nazmul Ahsan1,2, Yoshitaka Okada1,2. 1School of Engineering, The University of Tokyo, Tokyo, Japan, 2Research Center for Advanced Science and Technology (RCAST), The University of Tokyo, Tokyo, Japan. (505-H2) Optimization of the p-GaN Window Layer for InGaN/GaN Solar Cells. Carl J Neufeld, Zhen Chen, Samantha C. Cruz, Nikholas G. Toledo, Jim S. Speck, Umesh K. Mishra. University of California, Santa Barbara, Santa Barbara, CA, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

156


(506-H4) Temperature Characteristics Analysis of InGaP/InGaAs/Ge Triple-Junction Solar Cell under Concentrated Light using SPICE Diode Model. Yasuyuki Ota, Yuya Sakurada, Kensuke Nishioka. University of Miyazaki, Miyazaki, Japan. (507-H6) Structure and Composition of Lattice-Mismatched III-V Epilayers for High-Efficiency Photovoltaics. Monika Rathi1, Phil Ahrenkiel1, J. J. Carapella 2, M. W. Wanlass2. 1South Dakota School of Mines and Technology, Rapid City, SD, USA, 2NREL, Golden, CO, USA. (508-H8) Cell Efficiency Dependence on Solar Incidence Angle. Chitra Seshan. zettasun, Boulder, CO, USA. (509-H10) Metamorphic InGaP on GaAs and GaP for Wide-Bandgap Photovoltaic Junctions. John Simon, Stephanie Tomasulo, Paul Simmonds, Minjoo L. Lee. Yale University, Department of Electrical Engineering, New Haven, CT, USA. (510-H12) 2.0 – 2.1 eV GaxIn1-xP Solar Cells Grown on Relaxed GaAsP Step Grades. Myles A. Steiner, Ryan M. France, Mark W. Wanlass, Waldo J. Olavarria, Jeffrey J. Carapella, Anna Duda, Manuel J. Romero, John F. Geisz. National Renewable Energy Laboratory, Golden, CO, USA. (511-H14) Study of GaAsN Thin Film Structures by X-ray Reciprocal Space Mapping for Multi-Junction Solar Cell Application. Hidetoshi Suzuki1, Nobuaki Kojima2, Yoshio Ohshita2, Masafumi Yamaguchi2. 1University of Miyazaki, Miyazaki, Japan, 2Toyota Technological Institute, Nagoya, Japan. (512-H16) Identification of N-H Related Defects in GaAsN Grown by Chemical Beam Epitaxy. Tomohiro Tanaka, Hidetoshi Suzuki, Nobuaki Kojima, Yoshio Ohshita, Masafumi Yamaguchi. Toyota Technological Institute, Nagoya, Japan. (513-H18) InGaP/ GaAs /InGaAs Inverted Metamorphic (IMM) Solar Cells on 4” Epitaxial Lifted Off (ELO) Wafers. Rao Tatavarti1, Andree Wibowo1, Genevieve Martin1, Francis Tuminello1, Glen Hillier1, Chris Youtsey1, Noren Pan1, M. W. Wanlass2, Manuel Romero2. 1MicroLink Devices Inc., Niles, IL, USA, 2NREL, Golden, CO, USA. (514-H20) Efficiency Enhancement in Single-Junction InGaP Solar Cells by Using Self-Assembled Nanospheres. H. C. Chen, Y. L. Tsai, H. W. Wang, M. A. Tsai, P. C. Tseng, C. Y. Jang, Peichen Yu, H. C. Kuo. National Chiao Tung University,, Hsinchu, Taiwan. (515-H22) Efficiency Enhancement InGaP/GaAs Dual-junction Solar Cell with Sub-wavelength Antireflection Nanorod Arrays. H. W. Wang, M. A. Tsai, H. C. Chen, T. L. Tsai, P. C. Tseng, C. Y. Jang, Peichen Yu, H. C. Kuo. National Chiao Tung University, Hsinchu, Taiwan. (516-H24) Characterization of Thin-GaAs Films Grown on Nanostructured Si Substrates. Salvador Guel Sandoval1, M. Khizar Khan2, john Anderson3, Ron Manginell3, Greg Peake3, Nowshad Amin4, Kamaruzzaman Sopian4, Thomas Rotter5, Ganesh Balakrishnan5, Steve Brueck5, Saleem H. Zaidi2. 1Instituto de Investigación en Comunicación Óptica, of UASLP, Mexico, 2Gratings, Inc., Albuquerque, NM, USA, 3Sandia National Laboratories, Albuquerque, NM, USA, 4University Kebangsaan Malaysia, Bangi, Malaysia, 5University of New Mexico, Albuquerque, NM, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


157



Area 4: Posters, Crystalline Silicon: Crystallization, Modelling and Characterization

Chair(s): Jianming Fu, Daniel Kray (517-H26) Progresses on the Continuous Optical Fast CVD System to Grow Silicon Ribbons for Solar Cells via SDS Process. A Augusto, J M Serra, A M Vallêra. Faculty of Science University of Lisbon, Lisbon, Portugal. (518-H30) Inkjet Plating Resist for Improved Cell Efficiency. Robert Barr, Hua Dong. Dow Chemical Company, Marlborough, MA, USA. (519-H34) Low Cost, Low CO2 Emission Solar Grade Silicon. John R. Mott1, Julio A. Bragagnolo1, Michael P. Hayes2. 1MB Scientific Corporation, Walkersville, MD, USA, 2NC Consulting, Alliance, OH, USA. (520-I4) Floating Si-Foils for Photovoltaic Applications. Uri Cohen, Michael Roitberg. Ribbon Technology LLC, Palo Alto, CA, USA. (521-I8) An Investigation of the Thermal Gradients in Silicon During Multicrystalline Ingot Casting. Halvor Dalaker, Martin Syvertsen, Eivind J Øvrelid. SINTEF Materials and Chemistry, Trondheim, Norway. (522-I12) The Interactions Of Boron And Nitrogen In Liquid Silicon. Halvor Dalaker1, Merete Tangstad2. 1SINTEF Materials and Chemistry, Trondheim, Norway, 2Norwegian University of Science and Technology, Department of Materials Science and Engineering, Trondheim, Norway. (523-I16) A 2D Numerical Model Of Silicon Crystallisation. Halvor Dalaker. SINTEF Materials and Chemistry, Trondheim, Norway. (524-I20) A New DSS Furnace for Energy Saving in the Production of Multi-Crystalline Silicon. Fabrizio Dughiero, Michele Forzan, Dario Ciscato. University of Padova, Padova, Italy. (525-I24) PV Module Power Gain Due to Bifacial Design: Preliminary Experimental and Simulated Data. Lev Kreinin, Nelly Bordin, Asher Karsenty, Avishai Drori, Dov Grobgeld, Naftali Eisenberg. b-Solar, Jerusalem, Israel. (526-I28) Recent Developments with DSS Furnaces. P.S. Raghavan, Dean Skelton, Chandra P. Khattak. GT Solar Incorporated, Merrimack, NH, USA. (527-I32) A Study on the Optimal Position of Heater for Production of Single Crystal Solar Grade Ingot. Eunkuk Lee, Wonshoup So, JinSoo Park, JaeHak Jung. School of Display and Chemical Engineering, Yeungnam University, Gyeongsan, South Korea.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

158


(528-J2) Ultra-High Material-Quality Silicon Pillars on Glass. Fude Liu1, Mowafak Al-Jassim2, David Young2. 1The University of Hong Kong, Hong Kong, Hong Kong, 2National Renewable Energy Laboratory, Golden, CO, USA. (529-J6) Thermal Curing of Crystallographic Defects on a SLIM-Cut Silicon Foil. Alex Masolin1,2, Frederic Dross1, Jan Vaes1, Jef Poortmans1,2, Robert Mertens1,2. 1imec, Leuven, Belgium, 2Katholieke Universiteit Leuven, Leuven, Belgium. (530-J10) A Freeware Model for Precise Optical Analysis of the Front Surface of a Solar Cell. Keith R. McIntosh, Simeon C. Baker-Finch. Australian National University, Canberra, Australia. (531-J14) A Freeware Emitter Model for Silicon Solar Cells. Keith R. McIntosh1, Simeon C. Baker-Finch1, Pietro P. Altermatt2. 1Australian National University, Canberra, Australia, 2Leibniz University of Hannover, Hannover, Germany. (532-J18) Boron Removal from UMG-Si by Hybrid Melting Utilizing Steam Plasma Torch and EMCM. Byoung moon Moon1, Ho moon Lee1,2, Byung kwon Kim3,4, Dong ho Park4, Tae u Yu4. 1Production Technology R&D Divison, Korea Institute of Industrial Technology, Incheon, South Korea, 2Department of Metallurgical Engineering, Yonsei University, Seoul, South Korea, 3Department of Mechanical Engineering, Yonsei University, Seoul, South Korea, 4Green Chemistry & Manufacturing System R&D Div., Korea Institute of Industrial Technology, Cheonan, South Korea. (533-J22) Production of Low-Cost Solar-Grade Silicon by Reduction of SiF4 Gas with Metallic Sodium: Technical and Industrial Developmental Status. Angel Sanjurjo, Lorenza Moro, Kai Lau, Gopala Krishnan, Jordi Perez, Mark Hornbostel, Anoop Nagar, Brian Xie, JianEr Bao. SRI International, Menlo Park, CA, USA. (534-J26) Upgraded Metallurgy Grade Silicon and Monosilane by Alumothermal Recovering Route. Bolat N. Mukashev1, Khabibulla A. Abdullin1, Boris A. Beketov1, Marat F. Tamendarov1, Tleuzhan S. Turmagambetov1, Matthew R. Page2, David M. Kline2. 1Institute of Physics & Technology, Almaty, Kazakhstan, 2National Renewable Energy Laboratory, Golden, CO, USA. (535-J30) Diagnostic Structures for Epitaxial Thin Silicon Solar Cells. C. Paola Murcia1, Ruiying Hao1, Tim Creazzo1, Kevin Shreve1, Anthony Lochtefeld2, Michael Curtin2, Andrew Gerger2, Allen Barnett1. 1University of Delaware, Newark, DE, USA, 2AmberWave Systems, Salem, NH, USA. (536-J34) Light Trapping Enhancement in Thin Silicon Solar Cells Using Photonic Crystals. James G Mutitu, Shouyuan Shi, Allen Barnett, Dennis W. Prather. University of Delaware, Newark, DE, USA. (537-K4) Design Analysis of ZnO/cSi Heterojunction Solar Cells. Muhammad Nawaz1,2, Erik Stensrud Marstein2, Arve Holt2. 1University Graduate Centre (UNIK), Kjeller, Norway, 2Institute for Energy Technology (IFE), Kjeller, Norway. (538-K8) Characterization of Polycrystalline Silicon Films Produced by Aluminum-Induced Layer Exchange for the Various Thicknesses of an Aluminum Oxide Layer. H. Jeong, Kwang H. Oh, J. -H. Lee, S. Boo. KITECH, Gwangju, Korea.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


159


(539-K12) Investigation of a pc-Si Film Formed by a Local AIC Process Through a μm-sized Hole. Kwang H. Oh1, H. Jeong1, E. -O. Chi2, J. C. Kim2, S. Boo1. 1KITECH, Gwangju, Korea, 2OCI, Seongnam, Korea. (540-K16) Investigation of Aluminum Back Contact and BSF Formation for Silicon Solar Cells. Sungeun Park1, Jooyoung Song1, Chel-jong Choi2, Soonwoo Kwon3, Sewang Yoon3, Sung Ju Tark1, Min Gu Kang1, Hyunho Kim1, Seongtak Kim1, Donghwan Kim1. 1Korea University, Seoul, South Korea, 2Chonbuk National University, Jeonju, South Korea, 3TS corporation, Incheon, South Korea. (541-K20) Effect of Microstructure and Processing Parameters on Mechanical Strength of Multicrystalline Silicon Solar Cells. V.A. Popovich1, A. Yunus1, M. Janssen1, I.J. Bennett2, I.M. Richardson1. 1Delft University of Technology, Department of Materials Science & Engineering, Delft, Netherlands, 2Energy Research Centre of the Netherlands, Solar Energy, PV Module Technology, Petten, Netherlands. (542-K24) Two Dimensional Numerical Modeling of a Silicon Solar cell with Selective Emitter Configuration. Kalyan Rapolu1, Pritpal Singh1, Stephen P. Shea2. 1Department of Electrical and Computer Engineering, Villanova University, Villanova, PA, USA, 2Suniva Inc, Norcross, GA, USA. (543-K28) Simulation on the Grain Growth in the Multicrystalline Silicon Ingot Process. Wonshoup So, Jiyoun Park, Jin Soo Park, Minsu Kim, Eun Kuk Lee, Jae Hak Jung. Yeungnam university, Gyeongsan, South Korea. (544-K32) Influence of Defects and Defect Distributions in Multicrystalline Silicon on Solar Cell Performance. B. Sopori1, P. Rupnowski1, S. Shet1, V. Budhraja1, N. Call1, S. Johnston1, M. Seacrist2, G. Shi2, J. Chen2, A. Deshpande2. 1National Renewable Energy Laboratory, Golden, CO, USA, 2MEMC Electronic Materials, St. Peters, MO, USA. (545-L2) A Reflectance Spectroscopy Based Tool for High-Speed Characterization of Silicon Wafers and Solar Cells in Commercial Production. Bhushan Sopori1, Przemyslaw Rupnowski1, Debraj Guhabiswas1, Srinivas Devayajanam1, Chandra Khattak2, Matthew Albert2. 1National Renewable Energy Laboratory, Golden, CO, USA, 2GTSolar, Merrimack, NH, USA. (546-L6) Polycrystalline Silicon Thin Film for Solar Cells by Low-Temperature Aluminum Induced Crystallization Method. S. M. Yu1, Y. H. Yeh1, S. Y. Wei2, W. C. Sun1, T. S. Lin1, F. R. Chen2. 1Material & Chemical Research Laboratories, Industrial Technology Research Institute, Hsinchu, Taiwan, 2Department of Engineering and System Science Center for Transmission Electron Microcopy, National Tsing Hua University, Hsinchu, Taiwan. (547-L10) Characterization of a Very Low-Cost Silicon Cathode-Zinc Electrolyte Solar Cell. Babak Tousifar, Siavash Pourkamali. Department of Electrical and Computer Engineering, University of Denver, Denver, CO, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

160


(548-L14) Classification of Defects in Polycrystalline Si by Temperature Dependence of Electroluminescence under Forward and Reverse-biases. Shinichiro Tsujii, Emi Sugimura, Kenji Hirata, Takashi Saito, Ayumi Tani, Tomoaki Hatayama, Hiroshi Yano, Takashi Fuyuki. Graduate School of Materials Science, Nara Institute of Science and Technology (NAIST), Ikoma, Japan. (549-L18) ALD Al2O3 for Industrial Si Solar Cells: Advanced Cleaning and In-Depth Characterization. Bart Vermang1,2, Aude Rothschild2, Xavier Loozen2, Twan Bearda2, Emanuele Cornagliotti1,2, Joachim John2, Jef Poortmans1,2, Robert Mertens1,2. 1Katholieke Universiteit Leuven (KUL), Leuven, Belgium, 2Interuniversity Micro-electronic Center (IMEC), Leuven, Belgium. (550-L22) The Process-Induced Local Shunts in the Porous Silicon Etched Emitter Region of the Screen-Printed Silicon Solar Cell. P N Vinod. NPOL, Thrikkakara P.O, Cochin 682021, India. (551-L26) A MOS Model Developed for Studying Passivation Properties of Dielectric/ Semiconductor Interface. Jun Wang, Mahdi Farrokh-Baroughi. South Dakota State University, Brookings, SD, USA. (552-L30) Amorphous/Crystalline Silicon Heterojunction Solar Cells under Intensive Illumination. Qi Wang1, Matt R. Page1, Eugene Iwaniczko1, Yueqin Xu1, Lorenzo Loybal1, Anna Duda1, Falah Hasoon1, Scott Ward1, Dong Wang2, P.R. Yu2. 1NREL, Golden, CO, USA, 2Optony, Sunnyvale, CA, USA. (553-L34) Microstructure and Surface Chemistry of Nanoporous ‘Black Silicon’ for Photovoltaics. Yanfa Yan, Hao-Chih Yuan, Vernon E. Yost, Kim jones, Mowafak Al-Jassim, Howard M. Branz. National Renewable Energy Laboratory, Golden, CO, USA. (554-M4) The Dislocation Distribution Characteristics of a Multi-Crystalline Silicon Ingot and its Impact on the Cell Efficiency. Da You1, Jiabin Du1, Tao Zhang1, Yuepeng Wan1, ShanS Wu2, Lei Wang2, Deren Yang2. 1LDK Solar Co., Ltd, Xinyu, China, 2State Key Laboratory of Silicon Materials, ZheJiang Univ, Hangzhou, China. (555-M8) 2-D Numerical Simulation and Modeling of Monocrystalline Selective Emitter Solar Cells. Mauro Zanuccoli1, Pier Francesco Bresciani1, Michel Frei2, Hsiu-Wu Guo2, Hongbin Fang2, Mukul Agrawal2, Claudio Fiegna1, Enrico Sangiorgi1. 1ARCES-DEIS, University of Bologna and IUNET, Bologna, Italy, 2Applied Materials, Inc., Santa Clara, CA, USA. (556-M11) Purification of Solar Grade Silicon Using Electromagnetic Field. Lifeng Zhang, Anping Dong. Department of Materials Science and Engineering, Missouri University of Science & Technology, Rolla, MO, USA. (557-M13) Non-Metallic Particles in Solar Grade Silicon. Lifeng Zhang. Dept of Materials Science & Engineering, Missouri University of Science and Technology, Rolla, MO, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


161



Area 9: Posters, PV Modules & Systems: Performance and Systems

Chair(s): Katie Brown, Terry Jester (558-U15) Long Term Performance of PV Hybrid System in the Gobi Desert of Mongolia. Amarbayar Adiyabat1, Kenji Otani1, Namjil Enebish2, Nyamtsetseg Ivanov2, Byambatuya Dagva2. 1Research Center for Photovoltaics, AIST, Tsukuba, Japan, 2National Renewable Energy Center of Mongolia, Ulaanbaatar, Mongolia. (559-U17) Two Year Performance Analysis of a 14 MWdc Photovoltaic Plant in Las Vegas NV. Amine Alami Fettouhi. Fotowatio Renewable Ventures, San Francisco, CA, USA. (560-U19) Data Analysis of Solar Power Installation Project for Lee County’s T.K. Davis Justice Center. Henry W. Brandhorst, Julie A. Rodiek, Steve R. Best. Space Reseach Institute, Auburn University, AL, USA. (561-U21) Long Term Field Performance of Large Scale Thin-film Laminate Photovoltaic Power Systems: Lessons Learned at SMUD and Other Deployments. Donald E. Osborn. Amelio Solar/Spectrum Energy, Wilton, CA, USA. (562-U23) One Year Feedback on the First French PV Power Plant Equipped with 2-Axis Tracking. François Paponneau. Exosun,, France. (563-U25) Long-Term Performance of the First Grid-Connected, Building-Integrated Amorphous Silicon PV Installation in Brazil. Ricardo Ruther1, Lucas Nascimento1, Jair Urbanetz Junior2, Paulo Pfitscher1, Trajano Viana2. 1LABSOLAR/UFSC, Florianopolis, Brazil, 2LabEEE, Florianopolis, Brazil. (564-U27) Performance Assessment of a Microcrystalline Si PV Installation in a Warm Climate. Ricardo Ruther1,2, Jair Urbanetz Junior2, Trajano Viana2, Lucas Nascimento1, Paulo Pfitscher1. 1LABSOLAR/UFSC, Florianopolis, Brazil, 2LabEEE, Florianopolis, Brazil. (565-U29) Comparison Between Two 1 kW PV Grid-Connected Systems (One with a New Tracker and One Fixed). V. Salas1, M. Grases2, P. J. Debora1, C. Espadas2, C. Grases2, E. Olias1. 1Universidad Carlos III de Madrid, Leganes, Spain, 2Sendekia S.L., Madrid, Spain. (566-U31) Comparison Analysis of Measured and Estimated Yield of Grid-Connected PV System. Jung Hun So1, Byung Gyu Yu1, Hye Mi Hwang1, Jin Su Yoo1, Gwon Jong Yu1, Ju Yeop Choi2. 1Korea Institute of Energy Research, Daejeon, South Korea, 2Kwangwoon University, Seoul, South Korea. (567-U33) Large Scale PV System Monitoring-Modules Technology Intercomparison. Michal Krawczynski1, Matt Strobel1, Brian Goss1,2, Martin Bliss1, Thomas Betts1, Ralph Gottschalg1. 1Loughborough University, Loughborough, United Kingdom, 2Perpetual Energy, Knutsford, United Kingdom.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

162


(568-V1) PV Performance Models Require Validated Efficiency vs. Irradiance Measurements and Model Inputs. Ben Bourne, Matthew Donovan, Jeffrey Roche. SunPower Corp., Richmond, CA, USA. (569-V3) Comparing PV Simulation Models and Methods with Outdoor Measurements. Steve Ransome. SRCL, London, United Kingdom. (570-V5) Developing a Computational Tool to Assess Shadow Pattern on a Horizontal Plane, Preliminary Results. Rolando Soler-Bientz, Fernando Gomez-Castro, Lifter Ricalde-Cab. Energy Laboratory FIUADY, Merida, Mexico. (571-V7) Identifying Causes of Power Output Reduction in Photovoltaic Systems. Santiago Silvestre, A. Chouder. MNT-DEE-UPC, Barcelona, Spain. (572-V8) A Simple Nonlinear Model for the Effect of Partial Shade on PV Systems. Nikket Thakkar, Daniel Cormode, Vincent P.A. Lonij, Steve Pulver, Alexander D. Cronin. Physics Department, University of Arizona, Tucson, AZ, USA. (573-V10) Effect of Small Continuous Loads on System Efficiency. Bhumika Chhabra1, Rui Kamada1, Robert L. Opila1, Christiana B Honsberg2. 1University of Delaware, Newark, DE, USA, 2Arizona State University, Tempe, AZ, USA. (574-V12) Degradation of Different Photovoltaic Technologies Under Field Conditions. George Makrides1, Bastian Zinsser2, George E. Georghiou1, Markus Schubert2, Jürgen H. Werner2. 1University of Cyprus, Nicosia, Cyprus, 2Institut für Physikalische Elektronik (ipe) Universität Stuttgart, Stuttgart, Germany. (575-V14) Multi Solar (PVT) Co-Generation Power Station. Ami Elazari. Millennium Electric T.O.U. Ltd., Raanana, Israel. (576-V16) Development and Implementation of a Hybrid Photovoltaic System for Energy Support. Johann Alexander Hernández1, Johan Sebastian Patiño2, Juan Sebastian Tello2, Carlos Andres Arredondo3, Gerardo Gordillo3. 1Departamento de Ingeniería Eléctrica, Universidad Nacional de Colombia, Bogotá, Columbia, 2Departamento de Ingeniería Eléctrica, Universidad Distrital Fco. José de Caldas, Bogotá, Columbia, 3Departamento de Física, Universidad Nacional de Colombia, Bogotá, Columbia. (577-V18) Passive Cooling/Heating in Building Integrated Photovoltaic (BIPV). S.P. Singh, B.L. Bedi, M. Pathak, R.K. Bhogra. Amorphous Silicon Solar Cell Plant, Bharat Heavy Electricals Limited, C/O BHEL House, Sirifort,, New Delhi, India. (578-V20) Building Integrated Solar Power Generation on Roof. Guoguang Yu1,2, Huiqing Xu1, Jicai Ding1, Hongshan Xu2, Xianbi Xiang3, Xianbo Liao3. 1Hanxi TianJing New Energy Co.,LTd, Taiyuang, China, 2Yantai Dingcheng New Energy BIPV Engineering Co.,LTd., Yantai, China, 3Institute of Semiconductors, CAS, Beijing, China. (579-V22) A High-Performance Stand-Alone Solar PV Power System for LED Lighting. B. J. Huang, P. C. Hsu, M. S. Wu, K. Y. Chen. National Taiwan University, Taipei, Taiwan.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


163


(580-V24) Diffusion of Grid-Connected PV in India: An Analysis of Variations in Capacity Factor. Suryanarayana Doolla, Rangan Banerjee. Department of Energy Science and Engineering, IIT Bombay, Mumbai, India. (581-V26) Environmental Benefits of PV Powered Lighting Products for Rural Areas in South-East Asia: A Life Cycle Analysis with Geographic Allocation. Bart Durlinger, Angèle Reinders, Marten Toxopeus. Department of Design, Production and Management, University of Twente, Enschede, Netherlands. (582-V28) A Cost Analysis of Photovoltaic Technologies Under Jamaica’s Climatic Conditions. Darlene A Field, Claude McNamarah. University of the West Indies, Mona Campus, Kingston7, Jamaica. (583-V30) Solar Radiation Patterns in Yucatan Peninsula, Preliminary Analysis. Rolando Soler-Bientz, Lifter Ricalde-Cab. Energy Laboratory FIUADY, Merida, Mexico. (584-V32) Solutions for Deploying PV Systems in New York City’s Secondary Network Distribution Systems. Michael H. Coddington, Benjamin D. Kroposki, Kate H. Anderson, Thomas S. Basso. National Renewable Energy Laboratory, Golden, CO, USA. (585-V34) Statistical Modeling for Global Solar Radiation Forecasting in Bogota. Richard Perdomo, Edison Banguero, Gerardo Gordillo. Universidad Nacional de Colombia, Bogota, Columbia. (586-W2) A Comparison Between Thin Film and c-Si PV Technologies for MW Size Applications. Angelo Doni, Fabrizio Dughiero, Arturo Lorenzoni. Department of Electrical Engineering, University of Padova, Padova, Italy. (587-W5) Field Data Collection for Quantification of Reliability and Availability for Photovoltaic Systems. Elmer W. Collins, Michael J. Mundt, Jeff A. Mahn, Jennifer E. Granata, Michael A. Quintana. Sandia National Laboratories, Albuquerque, NM, USA.

TU

ES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

164


WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

WEDNESDAY JUNE 23POSTER PRESENTATIONS



Area 10: Posters, PV Velocity Forum-Streamlining Paths to Markets

Chair(s): John Benner (588-X1) PV LEGAL: Reduction of Bureaucratic Barriers for Successful PV Deployment in the EU. Paolo M Sonvilla1, Stanislaw M Pietruszko2. 1PV LEGAL project consortium, Berlin, Germany, 2Polskie Towarzystwo Fotowoltaiki, Varsaw, Poland. (589-X3) Strategies to Target Rural PV Market in Developing Countries – A Perspective. Chetan Singh Solanki, Siddharth Mudaliar. Indian Institute of Technology, Mumbai, India. (590-X5) Progress of Development of PV Systems in South-Eastern Poland. Jan M. Olchowik, K. Cieslak, S. Gulkowski, J. Mucha, M. Sordyl, K. Zabielski. Technical University of Lublin, Lublin, Poland. (591-X7) Overcoming Structural Engineering Barriers to PV Permits and Installations. Steve Dwyer1, Elizabeth Richards1, Tom Bosiljevac1, Kay Schindel2, Alan Harper2. 1Sandia National Laboratories, Albuquerque, NM, USA, 2City of Madison, Madison, WI, USA. (592-X9) How Changes in Patent Law are Altering the Landscape of Innovation. Clara Davis. Hollingsworth & Funk, Minneapolis, MN, USA. (593-X11) The Commercialization of Thin FIlm Technologies; Past, Present and Future. Paula Mints. Navigant Consulitng, Palo Alto, CA, USA. (594-X13) Development of Photovoltaics in Central and Eastern Europe. Stanislaw M. Pietruszko1, Kamila J. Błażejewska1, Doriana Malinovska2, Petko Vitanov2, Alexandros Stylianides3, Bronislav Bechnik4, Enn Mellikov5, Miklos Palfy6, Peteris Shipkovs7, Arunas Krotkus8, Peter Mifsud9, Dan Teodoreanu10, Zuzana Voderadska11, Franko Nemac12. 1Warsaw University of Technology, Centre for Photovoltaics, Warszawa, Poland, 2Bulgarian Academy of Sciences, Central Laboratory of Solar Energy and New Energy Sources,, Sofia, Bulgaria, 3Cyprus Institute of Energy, Nicosia, Cyprus, 4Czech Renewable Energy Agency, Prague, Czech Republic, 5Tallinn University of Technology, Tallinn, Estonia, 6Solart-System Engineering Ltd., Budapest, Hungary, 7Institute of Physical Energetics, Riga, Latvia, 8Semiconductor Physics Institute, Vilnius, Lithuania, 9Malta Resources Authority, Marsa, Malta, 10New Energy Sources Laboratory, Research Institute for Electrical Engineering, Bucharest, Rumania, 11Slovak Renewable Energy Agency, Bratislava, Slovakia, 12Energy Restructuring Agency, Ljubljana (Slovenia), Slovakia.


165


WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS10:30 - 12:00 PM Kamehameha Exhibit Hall III.a

Area 2: Posters, CIGS & CdTe: CIGS I and TCOs Chair(s): Harin Ullal, John Perkins (595-C22) Effect of Annealing for Ag-In-S Thin Films Prepared by a Vacuum Evaporation Method. Yoji Akaki1, Kyohei Yamashita2, Tsuyoshi Yoshitake2, Shigeyuki Nakamura3, Satoru Seto4, Takahiro Tokuda5, Kenji Yoshino5. 1Miyakonojo National College of Technology, Miyazaki, Japan, 2Kyushu University, Fukuoka, Japan, 3Tsuyama National College of Technology, Okayama, Japan, 4Ishikawa National College of Technology, Ishikawa, Japan, 5Miyazaki University, Miyazaki, Japan. (596-C25) Effect of Oxygen Partial Pressure and Annealing of Permittivty-Engineered ITO Studied by in-situ Ellipsometry. James M Burst1,2, Timothy J. Peshek1,3, Timothy A. Gessert1, Timothy J. Coutts1, XiaoNan Li1, Dean Levi1, Sharon M. Weiss4, Bridget R. Rogers5. 1National Center for Photovoltaics, NREL, Golden, CO, USA, 2Vanderbilt University, Interdisciplinary Materials Science, Nashville, TN, USA, 3Arizona State University, School of Materials, Tempe, AZ, USA, 4Vanderbilt University, Electrical Engineering and Computer Engineering, Nashville, TN, USA, 5Vanderbilt University, Chemical and Biomolecular Engineering, Nashville, TN, USA. (597-C28) Room-Temperature Fabrication of Highly Transparent Conductive Aluminum-doped Zinc Oxide Films. C. H. Chen1, Y. C. Chen1, S. F. Hong1, C. L. Wang1, W. C. Shih1, C. P. Tsai1, Y. C. Wu1, C. H. Lai1, C. N. Wei2, H. Y. Bor2. 1Department of Material Sciences and Engineering, National Tsing-Hua University, Hsinchu, Taiwan, 2MEOR, Chuang-Shan institute of Science and Technology, Taoyoun, Taiwan. (598-C31) Suppression of Deep Level Defects in CIGS Solar Cells using Proton Implantations. Min Soo Seol1, Do Hyung Kim1, Dong Wook Kwak1, Dong Wha Lee1, Jeung-Hyun Jeong 2, Hoon Young Cho1. 1Department of Physics, Dongguk University, Seoul, Korea, 2Thin Film Materials Design Lab, KIST, Seoul, Korea. (599-C34) Progress Toward a Stabilization and Preconditioning Protocol for Polycrystalline Thin-Film Photovoltaic Modules. Joseph A. del Cueto, Chris A. Deline, Steve R. Rummel, Allan Anderberg. National Renewable Energy Laboratory, Golden, CO, USA. (600-D3) Formation of a Conductive Grid on Thin Film Module Glass by Laser-Patterning for increased Module Efficiency. J Jaus, H Pantsar, O F Adurodija, M Duell, B Regaard, H Herfurth, D Doble. Fraunhofer CSE, Cambridge, MA, USA. (601-D6) Study Of Electrical And Morphological Properties Of AgInSe2 Thin Films Grown By Co-Evaporation. Carlos A Arredondo, Fredy G Mesa, Gerardo Gordillo. Universidad nacional de Colombia, Bogot·, Columbia. (602-D9) High Performance Dielectric and Barrier Coatings for Photovoltaic Systems. Todd Gudgel, Shrinivas Govindarajan, Sankar Sambasivan. Applied Thin Films, Inc., Evanston, IL, USA.

166


(603-D12) The Effect of the Mo Back Contact Microstructure on the CIGS Preferred Orientation and the Cell Efficiency. Ju-Heon Yoon1,3, Kwan-Hee Yoon1, Jong-Keun Kim1,4, Won-Mok Kim2, Jong-Keuk Park2, Taek Sung Lee2, Young-Joon Baik2, Tae-Yeon Seong3, Jeung-hyun Jeong1. 1Solar Cell Center, Korea Institute of Science and Technology, Seoul, Korea, 2Electronic Materials Center, Korea Institute of Science and Technology, Seoul, Korea, 3Department of Materials Science and Engineering, Korea University, Seoul, Korea, 4Department of Materials Science and Engineering, Korea Aerospace University, Seoul, Korea. (604-D15) Copper-Silver Chalcopyrites as Top Cell Absorbers in Tandem Photovoltaic and Hybrid Photovoltaic/Photoelectrochemical Devices. Jess M.M. Kaneshiro, Alexander Deangelis, Nicolas Gaillard, Yuancheng Chang, Jeremy Kowalczyk, Eric Miller. Hawaii Natural Energy Institute, University of Hawaiì at Manoa, Honolulu, HI, USA. (605-D18) ZnO Grown by Chemical Solution Deposition. Marit Kauk, Katri Muska, Mare Altosaar, Mati Danilson, Olga Volobujeva, Tiit Varema. Department of Materials Science, Tallinn University of Technology, Tallinn, Estonia. (606-D21) Advanced Sputtering of Amorphous Indium Zinc Oxide Transparent Conductors for Energy Applications. Jennifer E. Leisch1, Thomas Gennett1, Marie Galante2, John D. Perkins1, David S. Ginley1. 1NREL, Golden, CO, USA, 2Albion College, Albion, MI, USA. (607-D24) Heat Resistance of Ga-doped ZnO Films Deposited by Ion-Plating with DC-Arc Discharge: Impact of O2 Flow Rate During Deposition. Hisao Makino, Takahiro Yamada, Naoki Yamamoto, Tetsuya Yamamoto. Kochi University of Technology, Kami, Japan. (608-D27) In-situ and Ex-situ Studies of Molybdenum Thin Films Deposited by RF and DC Magnetron Sputtering. Himal Khatri, Sylvain Marsillac. University of Toledo, Toledo, OH, USA. (609-D30) Optical and Electrical Properties of Cu–In–Te Based Thin Films for 5% Efficient Solar Cells. Takahiro Mise, Tokio Nakada. Aoyama Gakuin University, 5-10-1 Fuchinobe, Sagamihara, Kanagawa, 229-8558, Japan. (610-D33) Electrical and Optical Characterization of FTO Thin Film Grown by Spray Method. Minoru Oshima, Kenji Yoshino. Universisty of Miyazaki, Miyazaki, Japan. (611-E2) Solution Deposition of Amorphous IZO Films by Ultrasonic Spray. Robert M. Pasquarelli1, Maikel F.A.M. van Hest2, Alexander Miedaner2, Calvin J. Curtis2, John D. Perkins2, Ryan P. O’Hayre1, David S. Ginley2. 1Colorado School of Mines, Golden, CO, USA, 2National Renewable Energy Laboratory, Golden, CO, USA. (612-E5) Influences of the Substrate Structures on the Growth of CuInSe2 and In2Se3 Thin Films. Dung-Ching Perng, Meng-Shian Tsai, Po-Yi Wu, Jia-Feng Fang. National Cheng Kung University, Tainan, Taiwan. (613-E8) Correlation between Preparation Parameters and Properties of Molybdenum Back Contact Layer for CIGS Thin Film Solar Cell. Eigo Takahashi, Shirish A. Pethe, Neelkanth G. Dhere. Florida Solar Energy Center, Cocoa, FL, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


167


(614-E11) On-Line, Real-Time, 100% Scribe Metrology. Timothy A Potts. Dark Field Technologies, Inc., Orange, CT, USA. (615-E14) Process Control of CIGS Manufacturing with NIR Metrology. Eugene Shalyt, Guang Liang, Peter Bratin. ECI Technology, Totowa, NJ, USA. (616-E17) Enhanced Reliability of Molybdenum by Al Doping after Damp-Heat Exposure for CIGS Solar Cells. C. L. Wang, W. C. Shih, C. H. Chen, Y. C. Chen, S. F. Hong, C.P. Tsai, Y. C. Wu, C. H. Lai. Department of Material Sciences and Engineering, National Tsing-Hua University, Hsinchu, Taiwan. (617-E20) Structure Optimization for a High Efficiency CIGS Solar Cell. Sang Ho Song1, Kushagra Nagaich1, Eray S. Aydil2, Rebekah K. Feist3, Robert Haley3, Stephen A. Campbell1. 1Dept. of ECE, University of Minnesota, Minneapolis, MN, USA, 2Dept. of CEMS, University of Minnesota, Minneapolis, MN, USA, 3Dow Chemical, Midland, MI, USA. (618-E23) Impacts of Humidity and Temperature on the Performance of Transparent Conducting Zinc Oxide. Melissa A. Yaklin, Duane A. Schneider, Kirsten M. Norman, Jennifer E. Granata, Chad L. Staiger. Sandia National Laboratories, Albuquerque, NM, USA. (619-E26) Data Mining-Aided Mapping of Structure-Property Relationships for Combinatorially Generated co-Doped ZnO Thin Films. Changwon Suh1, Chris W. Gorrie2, John D. Perkins1, Peter A. Graf1, Wesley B. Jones1. 1National Renewable Energy Laboratory, Golden, CO, USA, 2Department of Materials Science and Engineering, University of Florida, Gainesville, FL, USA. (620-E29) Structural Quality of CIGS Absorber Layers via Powder Evaporation and Solution Spray Deposition. Jeong Dae Suh, Ki Bong Song, Chang Woo Ham, Jung Min Cho, Eun Jin Bae. Eleconics and Telecommunications Research Institute, Daejeon, South Korea. (621-E32) Glass Cleaning and Its Effects on the Damp Heat Stability of Molybdenum on Soda-Lime Glass. Rajalakshmi Sundaramoorthy, John Pern, Adolfo Lazcano, Stephen Glynn, Joel Pankov, Tim Gessert. National Renewable Energy Lab, National Centre for Photovoltaics, Golden, CO, USA. (622-F1) Band Profile around Grain Boundary of Cu(InGa)Se2 Solar Cell Materials Characterized by Scanning Probe Microscopy. Masaki Takihara1, Takashi Minemoto2, Yoichi Wakisaka2, Takuji Takahashi1. 1Institute of Industrial Science, University of Tokyo, Tokyo, Japan, 2Department of Photonics, Ritsumeikan University, Siga, Japan. (623-F4) Effect of a Thin Sb Interlayer on the Selenization Process of CuInSe2. Bae-Heng Tseng, Yu-Yang Ho, Yu-Han Kuo. National Sun Yat-Sen University, Kaohsiung, Taiwan. (624-F7) Fabrication and Characterization of Cu(In,Ga)Se2 Thin-Film Solar Cells Prepared via the Solution Process. Chung-Hsien Wu, Chung-Hsin Lu. Department of Chemical Engineering, National Taiwan University, Taipei, Taiwan.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

168


(625-F9) SiO2 as Barrier Layer for Na Out-Diffusion from Soda-Lime Glass. Yanfa Yan, Xiaonan Li, Ramesh Dhere, mowafak Al-Jassim, Matt Young, Marty Scott. National Renewable Energy Laboratory, Golden, CO, USA. (626-F11) Non-Vacuum Process of CuInGaSe2 Films by CuInGaSe2 Paste. Kenji Yoshino, Ryuichi Tashiro, Tsuyoshi Tokuda, Akira Nagaoka. University of Miyazaki, Miyazaki, Japan. (627-F13) Growth of In-doped ZnO Films Grown by Non-vacuum Process. Kitaro Yoshizuru, Yujin Takemo, Kenji Yoshino. University of Miyazaki, Miyazaki, Japan. (628-F15) Electrical and Optical Characterization of Annealed Ga-doped ZnO Films Grown by a Reactive Plasma Deposition. Masato Shinmiya, Yujin Takemoto, Kenji Yoshino. University of Miyazaki, Miyazaki, Japan. (629-F17) Growth of AgInSe2 Crystals Grown by Non-vacuum Process. Hiroyuki Tsuru, Akira Nagaoka, Kenji Yoshino. University of Miyazaki, Miyazaki, Japan.


Area 7: Posters, Space Technologies Chair(s): Bernie Carpenter, David Chapman (630-Q23) Past, Present, and Future of NASA’s Photovoltaic Power Systems. Sheila G. Bailey1, Ryne Raffaelle2. 1NASA Glenn Research Center, Cleveland, OH, USA, 2NREL, Golden, CO, USA. (631-Q25) LEONE (>50 cm2) Space Solar Cells: Qualification, Production, Cost Reduction. Rina S Bardfield, Paul J Clapper, David M Peterson, Kiem B Bui, Julie J Hoskin, Bongim Jun, Surya K Sharma, James P Hanley. Spectrolab, Sylmar, CA, USA. (632-Q27) InGaN Devices for High Temperature Photovoltaic Applications. Chris Boney1,2, Ivan Hernandez1, Rajeev Pillai2, David Starikov1,2, Abdelhak Bensaoula3. 1Integrated Micro Sensors, Inc, Houston, TX, USA, 2Dept. of Physics, University of Houston, Houston, TX, USA, 3Depts. of Physics and Electrical Engineering, University of Houston, Houston, TX, USA. (633-Q29) Load Line Analysis On Solar Array Output Characteristics. Uma B.R., Ekkundi R.S., Sudhakar M, Sankaran M., Anil Agarwal. ISRO,ISAC, Bangalore, India. (634-Q31) Study the Effects of Proton Irradiation on GaAs/Ge Solar Cells. Dalia Elfiky, Masafumi Yamaguchi. Toyota Technological Institute, Nagoya, Japan. (635-Q33) Investigation and Modeling of Space Radiation Effects in Quantum Dot Solar Cells. Alex Fedoseyev1, Marek Turowski1, Edward W. Taylor2, Seth Hubbard3, Stephen Polly3, Alexander A. Balandin4. 1CFD Research Corporation, Huntsville, AL, USA, 2IPC Inc., Pagosa Springs, CO, USA, 3RIT, Rochester, NY, USA, 4UC Riverside, Riverside, CA, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


169


(636-R1) Space Solar Cell Edge, Interconnect, and Coverglsss Designs and Their Effect on Spacecraft Charging and Plasma Interactions. Dale C. Ferguson. AFRL/RVSV, Albuquerque, NM, USA. (637-R3) Single Crystalline GaAs Photovoltaics on Flexible Metal Substrates. Alex Freundlich1, Chandani Rajapaksha1, Andenet Alemu1, Akhil Mehrotra1, Senthil Sambandam2, Venkat Selvamanikham1. 1University of Houston, Houston, TX, USA, 2SuperPower Inc., Schenectady, NY, USA. (638-R5) Atomic Oxygen Degradation of MgF2 Anti-Reflection Films. N.J. Ianno1, Donna M.2. 1University of Nebraska-Lincoln, Lincoln, NE, USA, 2The Aerospace Corporation, El Segundo, CA, USA. (639-R7) Nuclear Weapons Effects Testing of Triple Junction Solar Cells. Phillip P. Jenkins1, Jonathan H. Fisher2, Kevin B. Fournier3, C. David Newlander2, Kelly M. Trautz1, Robert J. Walters1, Justin R. Lorentzen1, John F. Davis4, Steven W. Seiler4, Benjamin Cho5, Michael I. Eskenazi6. 1Naval Research Laboratory, Washington, DC, USA, 2GH Systems Inc., Huntsville, AL, USA, 3Lawrence Livermore Laboratory, Livermore, CA, USA, 4Alme and Associates, Alexandria, VA, USA, 5Emcore Corporation, Albuquerque, NM, USA, 6ATK Space, Goleta, CA, USA. (640-R9) Final Qualification Test Results of XTJ Triple Junction Space Solar Cell to AIAA – S-111 – 2005 and Spectrolab Test Standards. Bongim Jun, Chris M. Fetzer, Kaveh Rouhani, William G. Wise, Rina Bardfield, Kiem Bui, Dennis Hom, Mark S. Gillanders, Surya K. Sharma. Boeing, Sylmar, CA, USA. (641-R11) Thermal Annealing Study of Radiation Induced Defects in Nitride-Based Multi-Junction Solar Cell Structures. A. Khan1, S. Alsharif1, J. Gou2, A. Gapud1, M. Imaizumi3, M. Yamaguchi4, D.A. Rahman1. 1University of South Alabama, Mobile, AL, USA, 2University of Central Florida, Orlando, FL, USA, 3Japan Aerospace Exploration Agency, Tsukuba, Japan, 4Toyota Technological Institute, Nagoya, Japan. (642-R13) Rectifying Phenomenon of GaInP2/GaAs/Ge Solar Cell Under Low Temperature Conditions. LiangXing Wang, JianFeng Lu, MingBo Chen, WeiYing Chi, Depeng Jiang, MengYan Zhang, Wei Zhang, MengJia Wu, JianWen Xu, GuoXin Li. Shanghai Institute of Space Power Sources, Shanghai, China. (643-R15) Effects of Contamination on Solar Cell Coverglass. De-Ling Liu, Simon H. Liu, Keith R. Olson, Diana R. Allan, Chris J. Penatta. The Aerospace Corporation, El Segundo, CA, USA. (644-R17) Analysis of Record Photovoltaic Efficiencies from 1954 to 2009. Elisabeth L. McClure, Edward M. Gaddy. Johns Hopkins University Applied Physics Lab, Laurel, MD, USA. (645-R19) Optimized Device Design for Radiation Resistant and High Dislocation Solar Cells for Space Applications. Akhil Mehrotra, Alex Freundlich, Andenet Alemu. University of Houston, Houston, TX, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

170


(646-R21) Low Energy Proton Implantation Techniques for Coverglass Irradiation Qualification. Scott R. Messenger1, Kelly Trautz1, Robert J. Walters1, Glenn Jones2, James Hall2, John Schuur3. 1US Naval Research Laboratory, Washington, DC, USA, 2Qioptiq Space Technology, Wales, United Kingdom, 3Innovion Corporation, San Jose, CA, USA. (647-R23) Monte Carlo Analyses of the NEO Beam Electron Beam Facility for Space Solar Cell Radiation Qualification. Scott R. Messenger1, Jeffrey H. Warner1, Robert J. Walters1, Roberto Uribe2. 1US Naval Research Laboratory, Washingon, DC, USA, 2Kent State College of Technology, Kent, OH, USA. (648-R25) Optimization of Multi-junction Photovoltaic Devices for High Temperature Operations in Space and Solar Concentrator Applications. Sherif Michael. Naval Postgraduate School, Monterey, CA, USA. (649-R27) Solar Simulator AM0 Calibration Method. John C Nocerino, Simon H Liu. The Aerospace Corporation, El Segundo, CA, USA. (650-R29) Change in the Electrical Performance of InGaAs Quantum Dot Solar Cells due to Irradiation. Takeshi Ohshima1, Shin-ichiro Sato1, Chiharu Morioka2, Mitsuru Imaizumi2, Takeyoshi Sugaya3, Shigeru Niki3. 1Japan Atomic Energy Agency, Takasaki, Japan, 2Japan Aerospace Exploration Agency, Tsukuba, Japan, 3National Institute of Advanced Industrial Science and Technology, Tsukuba, Japan. (651-R31) Characterization of Solar Cell Degradation due to Electrostatic Discharge on Multi-Junction Solar Cell. Teppei Okumura1, Mitsuru Imaizumi1, Mengu Cho2. 1Japan Aerospace Exploration Agency, Tsukuba, Japan, 2Kyushu Institute of Technology, Kitakyushu, Japan. (652-R33) Switched Capacitor DC-DC Converter Based Maximum Power Point Tracking of a PV Source for Nano Satellite Application. Pradeep Peter1, Vivek Agarwal2. 1Indian Space Research Organisation, Bangalore, India, 2Indian Institute of Technology Bombay, Mumbai, India. (653-S1) U.S. Space Photovoltaic Roadmap. Brad Reed. Space and Missile Systems Center, Los Angeles Air Force Base, Los Angeles, CA, USA. (654-S3) Space Flight Experiment: Advanced Solar Cells & Protective Materials on the ISS Exterior. Theodore D. Sahlstrom1, Paul E. Hausgen2, David M. Wilt2, Alex D. Howard2, Michael D. Anderson, Jr.2, Neil A. Snyder1. 1Schafer Corporation, Space & Directed Energy Division, Albuquerque, NM, USA, 2Air Force Research Laboratory, Space Vehicles Directorate, Kirtland Air Force Base, NM, USA. (655-S5) Effects of Irradiation Beam Conditions on Radiation Degradation of Solar Cells. Masashi Saito1, Mitsuru Imaizumi2, Takeshi Ohshima3, Yasuo Takeda1. 1AES, Tsukuba, Japan, 2JAXA, Tsukuba, Japan, 3JAEA, Takasaki, Japan.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


171


(656-S7) Photo- and Dark Conductivity Variations of Solar Cell Quality a-Si:H Thin Films Irradiated with Protons. Shin-ichiro Sato1, Hitoshi Sai2, Takeshi Ohshima1, Mitsuru Imaizumi3, Kazunori Shimazaki3, Michio Kondo2. 1Japan Atomic Energy Agency, Gunma, Japan, 2National Institute of Advanced Industrial Science and Technology, Ibaraki, Japan, 3Japan Aerospace Exploration Agency, Ibaraki, Japan. (657-S9) Air Force ManTech Qualification of the 30% Class GaInP2/Ga(In)As/Ge Solar Cell to the AIAA S-111 Standard: Results and Recommendations. Mark Stan, Benjamin Cho, Brian Guzie, Vance Ley, Glen Smith, Paul Sharps, Tansen Varghese. Emcore Photovoltaics, Albuquerque, NM, USA. (658-S11) The Mars Surface Environment and Solar Array Performance. Paul M Stella, Jennifer A Herman. Jet Propulsion Laboratory, California Institue of Technology, Pasadena, CA, USA. (659-S13) Space Radiation Resistant Hybrid and Polymer Materials for Solar Cells. Edward W Taylor, Linda R Taylor. International Photonics Consultants, Pagosa Springs, CO, USA. (660-S15) Degradation Analysis of InGaP/GaAs/Ge Triple-Junction Solar Cells in High-Temperature and High-Light-Intensity Environments by Luminescence Techniques. Hiroyuki Toyota1, Takaaki Iwai2,1, Atsushi Murakami3,1, Mitsuru Imaizumi4, Michio Tajima1. 1ISAS/JAXA, Sagamihara, Japan, 2Meiji University, Kawasaki, Japan, 3The University of Tokyo, Bunkyo-ku, Japan, 4IAT/JAXA, Tsukuba, Japan. (661-S17) Electrical Characterization of Electron and Proton-Induced Defects in p+n GaAs Photodiodes: EBIC Study. Jeffrey H Warner1, Serguei I Maximenko2, Scott R Messenger1, Robert J Walters1, Steven A Ringel3, Mark R Brenner3, Andrew M Carlin3. 1Naval Research Laboratory, Washington, DC, USA, 2Global Defense Technology & Systems, Inc., Crofton, MD, USA, 3Ohio State University, Columbus, OH, USA. (662-S19) Optical Considerations in the Design of Direct-Bonded GaInP/GaAs/InxGa1-xAsyP1-y/InGaAs Four-Junction Space Solar Cells. Wei Zhang, Mengjia Wu, Depeng Jiang, Jianfeng Lu, Mingbo Chen. Shanghai Institute of Space Power Sources, Shanghai, China. (663-S21) High Temperature Measurement of the Spectral Emittance of Thermophotovoltaic Fabrication Materials. David S. Wolford, Donald L. Chubb, Eric B. Clark. NASA Glenn Research Center, Cleveland, OH, USA. (664-S23) Advances in Cell and Module Efficiency of a-Si:H and nc-Si:H Based Multi-Junction Solar Cells for Space and Near-Space Applications. Arindam Banerjee, Xixiang Xu, Kevin Beernink, Frank Liu, Ken Lord, Greg DeMaggio, Baojie Yan, Tining Su, Ginger Pietka, Chris Worrel, Scott Ehlert, Dave Beglau, Jeff Yang, Subhendu Guha. United Solar Ovonic LLC, Troy, MI, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

172



Area 8: Posters, PV Characterization: Module Characterization, Modeling and In-situ Process

Control Chair(s): Sylvain Marsillac, Yoshihiro Hishikawa (665-S25) Long Term Performance of PV Module in the Gobi Desert of Mongolia. Amarbayar Adiyabat1, Kenji Otani1, Enebish Namjil2, Enkhmaa Naruush3. 1Research Center for Photovoltaics, AIST, Tsukuba, Japan, 2National Renewable Energy Center, Ulaanbaatar, Mongolia, 3Meteorological Observation Center of Dornogobi, Sainshand, Mongolia. (666-S27) Performance Measurements at Varying Irradiance Spectrum, Intensity and Module Temperature of Amorphous Silicon Solar Cells. Martin Bliss, Thomas R Betts, Ralph Gottschalg. Centre for Renewable Energy Systems Technology (CREST), Department of Electronic and Electrical Engineering, Loughborough University, Loughborough, United Kingdom. (667-S29) Comparison of Photovoltaic Module Performance at Puu Waa Waa. Severine Busquet, Matthieu Dubarry, James Mitch Ewan, Bor Yann Liaw, Richard E. Rocheleau. Hawaii Natural Energy Institute, SOEST, University of Hawaii, Honolulu, HI, USA. (668-S31) Inline Phosphoric Acid Thickness and Uniformity Measurement System. David A Dorn, Stuart M McMuldroch. Specialized Imaging, Loveland, CO, USA. (669-S33) Real-Time Metrology of Self-Assembled Epitaxial Quantum Dots by RHEED. Chandani Rajapaksha, Alex Freundlich. Center for Advanced Materials and Physics Department, University of Houston, Houston, TX, USA. (670-T1) Determination of Charged State Density at the Interface Between Amorphous Silicon and Crystalline Silicon by Lateral Conductance Measurement. Kunal Ghosh, Clarence J. Tracy, Bill Dauksher, Stainslau Herasimenka, Christiana Honsberg, Stuart Bowden. Arizona State University, Tempe, AZ, USA. (671-T3) Influence of Nonuniformity of Irradiance within a Cell on the Accurate I-V Curve Measurement under 1-Sun Illumination. Yoshihiro HISHIKAWA, Haruya Shimura, Yuki Tsuno. AIST, Tsukuba, Japan. (672-T5) Analytical Improvements in PV Degradation Rate Determination. Dirk C. Jordan, Sarah R. Kurtz. National Renewable Energy Laboratory, Golden, CO, USA. (673-T7) Outdoor PV Degradation Comparison. Dirk C. Jordan, Ryan M. Smith, Carl R. Osterwald, Ed Gelak, Sarah R. Kurtz. National Renewable Energy Laboratory, Golden, CO, USA. (674-T9) Temperature of Solar Cells in Reverse Bias: Theory and Applications. Seung Rim, Maristel Baldrias, Mike Morse. SunPower Corp., San Jose, CA, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


173


(675-T11) In-situ Monitoring of CIGS Composition Ratio and the Crystal Quality by the Analysis of Raman Spectroscopy. Byoung Dong Kim1, Sang-Uk Ahn2, In-Hwan Choi3. 1Samsung Electronics, Yonging, South Korea, 2IPS-tech, Pyongtaek, South Korea, 3Chung-ang University, Seoul, South Korea. (676-T13) Step-Stress Accelerated Lifetime Testing for Photovoltaic Devices and Cells. Jinsuk Lee, Changwon Suh, Wesley B Jones. NREL, Golden, CO, USA. (677-T15) Evaluation of Methods for Correcting Photovoltaic Performance for Variations in Solar Spectrum. Bill F. Marion. National Renewable Energy Laboratory, Golden, CO, USA. (678-T17) Energy Rating of Various PV Module Technologies in Two Extreme Climates, Tropical and Cold-Arid Climate. Kenji Otani. AIST, Tsukuba, Japan. (679-T19) Effects of Load Connection on Accelerated Aging of a-Si:H Solar Cell for Long Term Reliability Test. Sang Hyun Park1, Kyung Min Kim1, Jun-Sik Cho1, Jeong Chul Lee1, Gi-Hwan Kang1, Duck-Kyun Choi 2, Kyung Hoon Yoon1, Jinsoo Song1. 1Photovoltaic research center, Korean Institute of Energy Research, Taejeon, Korea, 2Department of Ceramic Engineering, Hanyang University, Seoul, Korea. (680-T21) Estimation of Dual-Junction Solar Cell Characteristics Using Neural Networks. Jagdish C Patra. Nanyang Technological University, Singapore, Singapore. (681-T23) Observations on the Spectral Characteristics of Diode Breakdown Luminescence of Silicon Wafer Solar Cells. Matthew P. Peloso1, Pooja Chaturvedi1, Peter Würfel2, Bram Hoex1, Armin G. Aberle1. 1Solar Energy Research Institute of Singapore (SERIS), National University of Singapore (NUS), 7 Engineering Drive 1, 117574, Singapore, Singapore, 2Institut für Angewandte Physik, Universität Karlsruhe, 76131, Karlsruhe, Germany. (682-T25) The Effect of Uncertainty in Temperature Coefficients Used to Predict Energy Production with the Sandia Array Performance Model. Larry Pratt, David L King. Sandia National Labs, Albuquerque, NM, USA. (683-T27) From an Existing Large Area Pulsed Solar Simulator to a High Intensity Pulsed Solar Simulator: Characterization, Standard Classification and First Results at ESTI. Mauro Pravettoni1,2, Roberto Galleano2, Tuomas Aitasalo2, Robert P. Kenny2, Ewan D. Dunlop2, Keith W. J. Barnham1. 1Imperial College London, Blackett Laboratory, London, United Kingdom, 2European Commission, DG JRC, Institute for Energy, REU, Ispra (VA), Italy. (684-T29) Electrical Characterisation of Concentrating Photovoltaic Cells: a Comparison between Outdoor Testing under Direct Solar Radiation and Indoor Measurements on a High Intensity Solar Simulator. Mauro Pravettoni1,2, Matthew Norton3, Tuomas Aitasalo1, Roberto Galleano1, Georghiou George3, Robert P. Kenny1. 1European Commission - DG JRC, Ispra (VA), Italy, 2Imperial College London, Blackett Laboratory, London, United Kingdom, 3University of Cyprus, Department of Electrical and Computer Engineering, Nicosia, Cyprus.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

174


(685-T31) Three Test Field Clones Pave The Way to The Optimal Site-Related Photovoltaic Solution. Michael Wittner3, Timo Weber3, William Richardson1, Nicola Baggio2. 1SOLON Corporation, Tucson, AZ, USA, 2SOLON SpA, Carmignano di Brenta, Italy, 3SOLON SE, Berlin, Germany. (686-T33) Area Dependent Simulation Model for the Double Exponential Effect in I(V)-Characteristics of Solar Cells. Michael Sams, Christoph Lackner, Timm Ostermann. Johannes Kepler University, Linz, Austria. (687-U1) Novel 3-Diode Network Model for Concentrator MJ SCs Simulation. Maxim Z. Shvarts, Viktor M. Emelyanov, Vladimir M. Lantratov. Ioffe Physical-Technical Institute, Saint-Petersburg, Russia. (688-U3) FIB-SEM (Dual-Beam) for Large-Area and Site-to-Site EBIC Localization in Solar Photovoltaic Applications. Stacey Stone, Vihn Ngo, Michael Schmidt. FEI Company, Hillsboro, OR, USA. (689-U5) One Lateral Spectrum Splitting Concentrator Photovoltaic Architecture: Measurements of Current Assemblies and Analysis of Pathways to 40% Efficient Modules. Xiaoting Wang, Allen Barnett. Department of Electrical and Computer Engineering, University of Delaware, Newark, DE, USA. (690-U7) Fundamental Parameters Extraction From Dark I-V Characteristics: A Comprehensive Study On Amorphous/Crystalline Silicon Hetero-junction Solar Cells. Der-Chin Wu1, Jui-Chung Shiao1, Ching-Hsi Lin1, Chien-Hsun Chen1, Chih-Hung Liao1, Wei-Chih Hsu1, Wen-Haw Lu1, Fang-Yao Yeh1, Chung-Wen Lan1,2. 1Photovoltaics Technology Center, Industrial Technology Research Institute, Hsin-Chu, Taiwan, 2Department of Chemical Engineering,National Taiwan University, Taipei, Taiwan. (691-U9) Extracting Parameters from Semi-log Plots of Polycrystalline Silicon PV Modules Outdoor I-V Data: Double-exponential Model Revisited. Georgi H. Yordanov, Ole M. Midtgård, Tor O. Saetre. University of Agder, Grimstad, Norway. (692-U11) Energy Yield Study of a Commercial CIGS Module Using Outdoor and Indoor Testing. Toby Ferenczi, Marcus Zettl, Omar Stern, Eva Bernal, Mark Lynass, Oliver Mayer. GE Global Research, Garching, Germany.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


175



Area 9: Posters, PV Modules & Systems: Modules, Inverters and BOS Components

Chair(s): Ward Bower (693-U16) Grid Tied PV System Energy Smoothing. Thomas D. Hund, Sigifredo Gonzalez, Keith Barrett. Sandia National Labs, Albuquerque, NM, USA. (694-U18) PV Module-Integrated Thin-Layer Battery from Rice Hull Paper. Howard Somberg. Global PV Specialists, Woodland Hills, CA, USA. (695-U20) Modeling of a Solar Battery Charger based on PWM Buck-boost Converter Operated under Discontinuous Conduction Mode. Alberto Reatti1, Leonardo Serri1, Marian Kazimierczuk2. 1Department of Electronics and Telecommunications, Università degli Studi di Firenze, Firenze, Italy, 2Department of Electrical EngineeringWright State University, Dayton, OH, USA. (696-U22) Frequency-Domain Analysis of PWM DC-DC Converters Including Exact RMS Parasitic Resistances for Photovoltaic Applications. Alberto Reatti1, Leonardo Serri2, Marian Kazimierczuk3, Antonio Luchetta1. 1Department of Electronics and Telecommunications, Università degli Studi di Firenze, Firenze, Italy, 2Department of Energetics, Università degli Studi di Firenze, Firenze, Italy, 3Department of Electrical Engineering Wright State University, Dayton, OH, USA. (697-U24) Field Reliability Analysis Methods for Photovoltaic Inverters. John M. Fife1, Mesa Scharf1, Steven G. Hummel1, Russell W. Morris2. 1PV Powered, Bend, OR, USA, 2The Boeing Company, Seattle, WA, USA. (698-U26) Prediction of PV Module Nominal Operating Cell Temperature Using Electromagnetic Wave Modeling. Biao Li, Matthias Duell, Dan Doble. Fraunhofer Center for Sustainable Energy Systems, Cambridge, MA, USA. (699-U28) Preliminary Results of a Computational Tool to Model Low Concentration PV Modules. Rolando Soler-Bientz, Fernando Gomez-Castro, Lifter Ricalde-Cab. Energy Laboratory FIUADY, Merida, Mexico. (700-U30) The Solar Breeder Factory: Minimizing the Cost of Photovoltaic Energy Generation. Roger G. Little, Michael J. Nowlan, Robert D. Bradford. Spire Corporation, Bedford, MA, USA. (701-U32) Teflon® FEP Frontsheets for Photovoltaic Modules: Improved Optics Leading to Higher Module Efficiency. Sam L. Samuels1, Nicholas J. Glassmaker2, Gerald D. Andrews2, Michael J. Brown1, Mark E. Lewittes2. 1DuPont Photovoltaic Solutions, Wilmington, DE, USA, 2DuPont Central Research and Development, Wilmington, DE, USA. (702-U34) Improved Spectral Response of Silicone and EVA Encapsulated Photovoltaic Modules. Nick E. Powell, Byung K. Hwang, Ann W. Norris, Guy Beaucarne. Dow Corning Corporation, Midland, MI, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

176


(703-V2) Module Efficiency Increase by Colored Cell Connectors. Liv Proenneke, Michael Reuter, Gerda C. Glaeser, Juergen H. Werner. Institut für Physikalische Elektronik, Universität Stuttgart, Stuttgart, Germany. (704-V4) Equivalent Diagram of Photovoltaic Cell as an Element of Power System. Michael A. Slonim, Alexander A. Slonim. 1Ben-Gurion University, Beer Sheva,, Israel, 2Sami Shamoon College of Engineering, Beer Sheva,, Israel. (705-V6) Ion Beam Surface Modification of Solar Module Glass for Reduced Reflectance. Mark B. Spitzer. Photonic Glass Corporation, Norwood, MA, USA. (706-W4) World First 17%-Efficient Multi-Crystalline Module. Caroline Tjengdrawira, Machteld Lamers, Ian Bennett, Paul C. de Jong. Energy Research Center of the Netherlands, Petten, Netherlands. (707-V9) The Effect of Reverse Current on Hot Spot in Crystalline Silicon Solar Cells. Hong Yang. Xi’an Jiaotong University, Xi’an, China. (708-V11) A Novel Photovoltaic Module Assembled Three-Dimensionally. Yuji Asai, Toshiaki Yachi. Yachi Laboratory, Department of Electrical Engineering, Graduate School of Engineering, Tokyo, Japan. (709-V13) Potential Induced Degradation of Solar Cells and Panels. Juliane Berghold, Oliver Frank, Sebastian Pingel, Henry Hoehne, Markus Winkler. SOLON SE, Berlin, Germany. (710-V15) Performance of Metal Wrapped-Through Solar Module. Hsinhsin Hsieh. Industrial Technology Research Institute, Hsinchu, Taiwan. (711-V17) Outdoor Energy Rating and Spectral Effects of Photovoltaic Modules. Radhika Lad1, GovindaSamy TamizhMani1, John Wohlgemuth2. 1Arizona State University - Photovoltaic Reliability Laboratory (ASU-PRL), Mesa, AZ, USA, 2BP Solar, Frederick, MD, USA. (712-V19) Monolithic Integrated Solar Energy Harvesting System. Edgardo Mendes, Eduardo I. Ortiz-Rivera, Gillermo Serrano. University of Puerto Rico-Mayaguez, Mayaguez, PR, USA. (713-V21) Test-to-Failure of PV Modules: Hot-Spot Testing. Janu Mathew1, Govindasamy TamizhMani1,2, Joseph Kuitche2. 1Arizona State University, Polytechnic campus, Mesa, AZ, USA, 2TUV Rheinland, Tempe, AZ, USA. (714-V23) Research on the Z-Source Inverter Grid-Connected Control of Micro-Grid based on Differential Geometry. Yan Chen, Lin Zhou, Qiang Liu, Zhiguo Zhang. State Key Laboratory of Transmission & Distribution Equipment and Power System Safety and New Technology, Chongqing, China. (715-V25) A Novel Technique for THD Control in Grid Connected Photovoltaic Systems using Step Variable Inductor Approach. Rupesh Wandhare, Vivek Agarwal. Department of Electrical Engineering, IIT Bombay, Mumbai, India.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


177


(716-V27) PV Array Simulator Development and Validation. Sigifredo Gonzalez1, Scott S. Kuszmaul1, Don Deuel2, Roberto Lucca2. 1Sandia National Laboratories, Albuquerque, NM, USA, 2Ametek Programmable Power, San Diego, CA, USA. (717-V29) Performance Analysis of Photovoltaic Chain-cell Inverter using Digital Signal Processor (DSP). Nagaraju J, Dinesh Naik, G. P. Raghavendra Yasasvi. Indian Institute of Science, Bangalore. 560012, India. (718-V31) A Low Cost High Efficiency Inverter for Photovoltaic AC Module Application. Yanlin Li, Ramesh Oruganti. Department of Electrical and Computer Engineering, National University of Singapore, Singapore, Singapore. (719-V33) An Efficient Cascaded Multilevel Inverter Suited for PV Application. Hirak C. Patangia, Dennis M. Gregory. University of Arkansas-Little Rock, Little Rock, AR, USA. (720-W1) Inverter-Utility Resonant Stability in PV Systems. Eric A. Seymour, Karen E. Robinson. Advanced Energy Industries, Fort Collins, CO, USA. (721-W3) Material Impacts on ECN’s Back-Contact Module Reliability. Manuel G. Guichoux, Caroline Tjengdrawira, Dirk Veldman, Paul C. de Jong. Energy Research Center of the Netherlands, Petten, Netherlands. (722-W6) Materials Considerations for PV Markets: Guideposts for Technology Directions. Igor J. Malik, Elmira Ryabova, Andrew Skumanich. SolarVision Co, Los Gatos, CA, USA. (723-W8) Materials and Manufacturing Processes for Flexible Photovoltaic Modules. Jelena Muric-Nesic, Andrew Blakers, Maureen Brauers, Erin Davies, Vernie Everett, Rowena Mankelow, Igor Skryabin, Elizabeth Thomsen, Huanhuan Zhao. CSES, Australian National University, Canberra, Australia. (724-W10) Technology Roadmap for PV Manufacturing: Combining a Technical and Market Perspective. Andrew Skumanich, Elmira Ryabova, Igor J Malik, Shekar Reddy, Lalit Sabnani. SolarVision Co, Los Gatos, CA, USA. (725-W12) Energy Yields of 14 PV Modules - One Year Test Data in Madrid (Spain). M. Alonso Abella, F. Fabero, N. Vela, F. Chenlo. Ciemat, Madrid, Spain. (726-W14) Microgrid Efficiency Enhancement based on Neuro-fuzzy MPPT Control for Photovoltaic Generator. Aymen Chaouachi, Rashad M. Kamel, Ken Nagasaka. Tokyo University of Agriculture and Technology, Tokyo, Japan. (727-W16) 360° Sun Tracking with Automated Cleaning System for Solar PV Modules. Ravi Tejwani, Chetan S. Solanki. Indian Institute of Technology, Mumbai, India. (728-W18) Comparative Study of Various PV Technologies in Terms of Energy Yield and Annual Degradation. Neelkanth G. Dhere, Shirish A. Pethe, Ashwani Kaul. Florida Solar Energy Center, Cocoa, FL, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

178


(729-W20) Optimum Tracking Angles Using Pseudo-Equatorial Coordinates. Liang Gao1.2, Shijun Cai2.3, Peng Gao2, Palvin Chan2, Tuo Zhu1.4, Zhengrong Shi1,2,3. 1JiangNan University, Wuxi, China, 2Suntech Power Co.,Ltd, Wuxi, China, 3Jiangsu (Suntech) Institute for Photovoltaic Technology, Wuxi, China, 4HeHai University, Wuxi, China. (730-W22) A Method for Instantaneous Measurement of PV V-I Characteristics and its Application for MPPT Control. Daohong Wang. Gifu University of Japan, Gifu, Japan.


Area 1: Posters, Fundamentals & New Concepts: Novel Mechanisms and Materials

Chair(s): Ryne Raffaelle, Yoshitaka Okada, Nicholas Ekins-Daukes (731-A2) A New Look at Si Inversion-Layer Solar Cells, Where Inorganic, Molecular and Organic Electronics Meet. David Cahen. Weizmann Institute of Science, Rehovot, Israel. (732-A5) A Semi-analytical Model for Semiconductor Solar Cells: From Fundamental Limits to Real Materials. Ding Ding, Shane R. Johnson, Yong-Hang Zhang. Center for Nanophotonics and School of Electrical, Computer, and Energy Engineering, Tempe, AZ, USA. (733-A8) Generalized Charge Transport Model for Organic/Inorganic Material Systems: Model Description and Applications for Large Junction Area Solar Cells. Seyyed Sadegh Mottaghian1, Mahdi Farrokh Baroughi1, Khadijeh Bayat1, Matt Biesecker2, Jung-Han Kimn2. 1Electrical Eng. & Comp. Sci., South Dakota State University, Brookings, SD, USA, 2Math Department, South Dakota State University, Brookings, SD, USA. (734-A11) Au Core-Shell Nanoparticle- PVP Based Coating for Efficiency Enhancement of Solar Cells. Ian Sear, Marine Gasulla, Andenet Alemu, Alex Freundlich. Photovoltaics and Nanostructures Laboratory, Center for Advanced Materials, University of Houston, Houston, TX, USA. (735-A14) Efficiency Limits of Multi-junction Photovoltaic Systems. Jeffery L Gray, Jonathan M Schwarz, John R Wilcox, Alexander W Haas, Richard J Schwartz. School of Electrical and Computer Engineering, Purdue University, West Lafayette, IN, USA. (736-A17) Complete Photonic Bandgap Calculations and its Application to Thin-Film Solar Cells. Md. Ahsan Habib, Muhammad Sharifuzzam Khan, Chowdhury Golam Sufi Al-amin, Saeed Mahmud Ullah, Shahida Rafique. Applied Physics, Electronics & communication Engineering, University of Dhaka, Dhaka, Bangladesh. (737-A20) Theoretical and Experimental Study of the Controlled Size and Shape Nanostructure for Thermoelectric and Photovoltaic Applications. Nicoleta Z Hickman, Kris Davis. Florida Solar Energy Center, Cocoa, FL, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


179


(738-A23) Design Optimization of Series-Parallel Triple-Junction Solar Cells. Tzu-Wen Hsieh, Peichen Yu. National Chiao Tung University, ROC, Hsinchu, Taiwan. (739-A30) Coupled Atomistic and Continuum Modeling of Elastic Effects of Point Defects in Crystalline Photovoltaics. ShinYoung Kang, Maria K Chan, Gerbrand Ceder. Massachusetts Institute of Technology, Cambridge, MA, USA. (740-A33) Phonon Assisted Absorption Enhancement in Amorphous Si Solar Photovoltaic. Jedo Kim, Massoud Kaviany. Department of Mechanical Engineering and Applied Physics Program, University of Michigan, Ann Arbor, MI, USA. (741-B2) Detailed Balance Calculations of Multiple Exciton Generation and Tandem Hybrid Solar Cells. Jongwon Lee, Honsberg Christiana. Arizona State University, Tempe, AZ, USA. (742-B5) Synthesis of CuO, Cu2O, and Cu-Ti Oxide Thin-Films by RF Magnetron Sputtering. Houwen Tang1,2, Le Chen2, Sudhakhar Shet2, Yanfa Yan2, Mowafak Al-Jassim2, John Turnar2, Mohammad Matin1. 1University of Denver, Denver, CO, USA, 2National Renewable Energy Laboratory, Golden, CO, USA. (743-B8) Nanoporous Silicon Antireflection Coatings Obtained by Various Methods of Electrochemical Etching for Silicon Solar Cells. Toktar I. Taurbayev1, Viktor Yu. Timoshenko2, Valeriy E. Nikulin1, Gauhar K. Mussabek1, Yerzhan T. Taurbayev1, Kadyrzhan K. Dikhanbayev1. 1al-Farabi Kazakh National University, Almaty, Kazakhstan, 2M.V. Lomonosov Moscow State University, Moscow, Russia. (744-B11) Calculations of Enhanced Light Absorption in Thin-Film Si Solar Cells by Dielectric Scattering. James R Nagel, Michael A Scarpulla. University of Utah, Salt Lake City, UT, USA. (745-B14) Silicon Ultra-Doped with Chalcogens for Photovoltaic Devices. Bonna K. Newman1, Joeseph Sullivan1, Mark Winkler1, Elif Ertekin1, Meng-Ju Sher2, Yu Ting Lin2, Matthew A. Marcus3, Sirine Fakra3, Eric Mazur2, Jeff C. Grossman1, Tonio Buonassisi1. 1Massachusetts Institute of Technology, Cambridge, MA, USA, 2Harvard University, Cambridge, MA, USA, 3Advanced Light Source, Lawrence Berkeley National Laboratory, Berkeley, CA, USA. (746-B17) Enhancement of Electromagnetic Field Intensity by Metallic Photonic Crystal for Efficient Upconversion. Hari P. Paudel1, Khadijeh Bayat 1, Mahdi Farrokh Baroughi1, Stanley May2, David W. Galipeau1. 1Department of Electrical Engineering and Computer Science, South Dakota State University, Brookings, SD, USA, 2Department of Chemistry, University of South Dakota, Vermillion, SD, USA. (747-B20) Metal-Insulator-Metal Point-Contact Diodes as a Rectifier for Rectenna. Prakash Periasamy1, Jeremy Bergeson2, Philip Parilla2, David Ginley2, Ryan O’Hayre1. 1Colorado School of Mines, Golden, CO, USA, 2National Renewable Energy Laboratory, Golden, CO, USA. (748-B23) Doped Bi-Se Thin-Films for Photovoltaic Applications. Sovannary Phok, Philip Parilla, Rajeev N Kini, Raghu Bhattacharya, Bobby To, Joel Pankow. National Renewable Energy Laboratory, Golden, CO, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

180


(749-B30) Broadband Characteristics of Surface Plasmon Enhanced Solar Cells. Brian J Roberts, Pei-Cheng Ku. University of Michigan, Ann Arbor, MI, USA. (750-B33) Uniform Embedment of CdSe/ZnS Quantum Dot Arrays in Thin Oxide Layers for Luminescence Down Shifting in PV Devices. Bahareh Sadeghimakki1,2, Siva Sivoththaman1,2. 1Centre for Advanced Photovoltaic Devices and Systems (CAPDS), Waterloo, ON, Canada, 2Department of Electrical and Computer Engineering, University of Waterloo, Waterloo, ON, Canada. (751-C2) Novel BSF Structure Formation by Modified Sol-Gel Method For Low Cost New Cell Concept Implementation. Elmira Ryabova, Andrew Skumanich, Igor J Malik. SolarVision Co, Los Gatos, CA, USA. (752-C5) Chemical Bath Deposition (CBD) of Iron Sulfide Thin-Films for Photovoltaic Applications, Crystallographic and Optical Properties. Peethambaram Prabukanthan1, Rodney J Soukup1, Natale J Ianno1, Amitabha Sarkar1, Chad A Kamler1, Christopher L Exstrom2, Jiri Olejnícek2, 3, Scott A Darveau2. 1University of Nebraska, Lincoln, NE, USA, 2University of Nebraska, Kearney, NE, USA, 3Institute of Physics, Academy of Sciences, Prague, Czech Republic. (753-C8) Photoresponse Properties of BaSi2 Films Grown on n+-BaSi2/p+-Si Tunnel Juntion for High Efficiency Thin-Film Solar Cells. Takanobu Saito1, Yuta Matsumoto1, Takashi Suemasu1,2, Noritaka Usami3. 1University of Tsukuba/, Institute of Applied Physics, Japan, Tsukuba, Japan, 2PRESTO of Japan Science and Technology Agency, Tokyo, Japan, 3Tohoku University, Institute of Materials Research, Sendai, Japan. (754-C11) Development of ZnTe1-xOx Intermediate Band Solar Cells. Tooru Tanaka1,2, Kin Man Yu1, Peter Stone1,3, Jeffrey W. Beeman1, Oscar Dubon1,3, Lothar A. Reichertz1,4, Vincent M. Kao1, Mitsuhiro Nishio2, Wladek Walukiewicz1. 1Materials Sciences Division, Lawrence Berkeley National Laboratory, Berkeley, CA, USA, 2Department of Electrical and Electronic Engineering, Saga University, Saga, Japan, 3Department of Materials Science and Engineering, University of California, Berkeley, CA, USA, 4RoseStreet Labs Energy, Phoenix, AZ, USA. (755-C13) Efficiency of a Laterally Engineered Architecture for Photovoltaics. Ethan R. Torrey, Jennifer Krohn, P. Paul Ruden, Philip I. Cohen. University of Minnesota, St. Paul, MN, USA. (756-C15) Evaluation of Minority Carrier Lifetime in BaSi2 as a Novel Material for Earth-Abundant High Efficiency Thin-Film Solar Cells. Noritaka Usami1, Takanobu Saito2, Akiko Nomura1, Toetsu Shishido1, Takashi Suemasu2,3. 1Tohoku University, Sendai, Japan, 2University of Tsukuba, Tsukuba, Japan, 3PRESTO, Japan Science and Technology Agency, Tokyo, Japan. (757-C17) Optimization of Multi-Junction Solar Cell Performance in the Infrared by Application of Thin-Film Si:Ge Solar Cells. Yi Wang1, Anthony Lochtefeld2, Ji-Soo Park2, Christopher Kerestes1, Robert Opila3, Allen Barnett1. 1Department of Electrical Engineering, University of Delaware, Newark, DE, USA, 2AmberWave Systems Corp, Salem, NH, USA, 3Department of Material Science, University of Delaware, Newark, DE, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


181


(758-C18) Photo-Generated Charge Collection in Solar Cells. Kanglin Xiong, Shulong Lu, Taofei Zhou, Rongxin Wang, Kai Qiu, Jianrong Dong, Hui Yang. Suzhou Institute of Nano-tech and Nano-bionics, SuZhou, China. (759-C19) Photovoltaic Applications of Fluorine-Containing AR Coating. Toru Yoshida1, Yasukazu Kishimoto2. 1TOSOH F-Tech, Inc., 4988, Kaisei, Shunan 746-0006, Japan, 2TOSOH F-Tech, Inc., Shiba-Koen First Building, 3-8-2, Shiba, Minato, Tokyo 105-0014, Japan. (760-C20) Mechanism Probing on the Interactions Between the Dielectric Liquids and the Solar Cells Immersed Inside. Yiping Wang, Zhengjian Zhao, Li Zhu. Tianjin University, Tianjin, China.


Area 3: Posters, III-V’s & Concentrators: Concentrator Systems

Chair(s): Bob Cart, Frank Dimroth (761-F19) Analysis of Shadow by CPV Panels for Agriculture Application. Kenji Araki1, Atsushi Akisawa2, Isao Kumagai1, Hirokazu Nagai1. 1Daido Steel, Nagoya, Japan, 2Tokyo University of Agriculture and Technology, Tokyo, Japan. (762-F21) Comparative Thermal Analysis of Solar Cells Mounted on Ceramic and Metallic Carriers under High Concentration Conditions. Osvaldo Arenas1, Simon Chow2, Jeffrey F. Wheeldon2, Louis-M. Collin1, Christopher E. Valdivia2, Karin Hinzer2, Luc Frechette1, Vincent Aimez1, Richard Arès1. 1Centre de Recherche en Nanofabrication et en Nanocaractérisation,CRN², Université de Sherbrooke, Sherbrooke, QC, Canada, 2Centre for Research in Photonics, University of Ottawa, Ottawa, ON, Canada. (763-F23) A New 960x Concentrating System with High Tracking Error Tolerance and Low Cost. Humayun A Mughal1, Timothy M Bruton2. 1Silicon CPV, Harlow, United Kingdom, 2TMB Consulting, Woking, United Kingdom. (764-F25) Low Cost CPV = Embedded CPV with Internal Tracker. Robert O Campbell, Michael G Machado. zettasun, Boulder, CO, USA. (765-F27) Variation In Spectral Irradiance And The Consequences For Multi-junction Concentrator Photovoltaic Systems. Ngai L A Chan, Thomas B Young, Helen E Brindley, Balarko Chaudhuri, Ned J Ekins-Daukes. Imperial College London, London, United Kingdom. (766-F29) Solar Flux Distribution Analysis of non-Imaging Planar Concentrator for the Application in Concentrator Photovoltaic System. Kok-Keong Chong, Chee-Woon Wong, Fei-Lu Siaw, Tiong-Keat Yew. Universiti Tunku Abdul Rahman, Kuala Lumpur, Malaysia.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

182


(767-F31) Open-Loop Azimuth-Elevation Sun-Tracking System using on-Axis General Sun-Tracking Formula for Achieving Tracking Accuracy of below 1 mrad. Kok-Keong Chong, Chee-Woon Wong. Universiti Tunku Abdul Rahman, Kuala Lumpur, Malaysia. (768-F33) Portable Concentrating Solar Power Supplies. Lewis M Fraas1, Leonid Minkin1, James Avery1, Han X Huang1, Jany X Fraas1, Parvez Uppal2. 1JX Crystals Inc, Issaquah, WA, USA, 2Arny Research Lab, Adelphi, MD, USA. (769-G1) A Method of Optical Design and Construction for Low-Cost Cassegranian type Solar Concentrators. Declan J. Gordon, Alan P. Morrison. Department of Electrical Engineering, University College Cork, Cork, Ireland. (770-G3) Numerical Analysis of Direct Liquid-Immersed Solar Cell Cooling of a Linear Concentrating Photovoltaic Receiver. Xin yue Han1,2, Vernie Everett2, Yi ping Wang1,3, Li Zhu3. 1School of Chemical Engineering and Technology, Tianjin University, Tianjin, China, 2Centre for Sustainable Energy Systems, Australian National University, Canberra, Australia, 3School of Architecture, Tianjin University, Tianjin, China. (771-G5) An Innovative Solar System with High Efficiency and Low Cost. Lili He1, Donald Wagner2. 1San Jose State University, san jose, CA, USA, 2Sol-Solutions, Inc.,, Los Altos, CA, USA. (772-G7) Site Data Analysis of SolFocus CPV Systems. Christophe King. SolFocus, Mountain View, CA, USA. (773-G9) Optimal Cell Connections for Improved Shading, Reliability, and Spectral Performance of Microsystem Enabled Photovoltaic (MEPV) Modules. Anthony L. Lentine, Gregory N. Nielson, Murat Okandan, William C. Sweatt, Jose L. Cruz-Campa, Vipin P. Gupta. Sandia National Laboratories, Albuquerque, NM, USA. (774-G11) Evaluation of a CPV System with Beam-Splitting Features for Hydrogen Generation. Alaeddine Mokri, Mahieddine Emziane. Masdar Institute of Science and Technology, Abu Dhabi, United Arab Emirates. (775-G13) A Gravity Independent Integrated Passive Cooler for Solar Cell Efficiency Improvement. Laurent MONTES, Bogdan BERCU. IMEP-LAHC, Minatec, GRENOBLE, France. (776-G15) 3-Dimensional Simulator for Concentrator Photovoltaic Modules using Ray-Trace and Circuit Simulator. Yasuyuki Ota, Kensuke Nishioka. University of Miyazaki, Miyazaki, Japan. (777-G17) The Optimization of the Immersion Liquid Cooling CPV Receiver. huang qunwu, wang yiping, zhu li. Tianjin University, Tianjin, China. (778-G19) Development and Characterisation Of a Novel Low Concentrating Building Integrated Photovoltaic System. Nabin Sarmah, Tapas K Mallick. Heriot Watt University, Edinburgh, United Kingdom. (779-G21) Aggregated Total Internal Reflection Optics for Solar. David S Schultz, Chris S Grimmer, Kevin Fine. Banyan Energy Inc., Berkeley, CA, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


183


(780-G23) CPV: Not Just for Hot Deserts!. Chitra Seshan. zettasun, Boulder, CO, USA. (781-G25) Concentrating Photovoltaic Multi-Junction Module Electrical Lay-out Optimisation by a New Theoretical and Experimental “Mismatch” Analysis Including Series Resistance Effects. Gianuca Timo’1, Alessandro Minuto1, Piero Groppelli1, Matthias Sturm2. 1ERSE, Piacenza, Italy, 2Solartec International AG, Aschheim, Germany. (782-G27) Concept and Design of “Flat-Plate” CPV Module Based on Ring-Array Concentrator. Sergiy Vasylyev, Viktor Vasylyev, Vladislav Sergeev. S.V.V. Technology Innovations, Sacramento, CA, USA. (783-G29) A Hybrid Solar Linear Concentrator Prototype in India. Marta Vivar1, Joseph Daniel2, Igor L Skryabin1, Vernie A Everett1, Andrew W Blakers1, L Suganthi2, S Iniyan2. 1Centre of Sustainable Systems, Australian National University, Canberra, Australia, 2Department of Management Studies and Department of Mechanical Engineering, Anna University, Chennai, India. (784-G31) Integrating the Design and Reliability Assessment of a Hybrid PV/Thermal Microconcentrator System. Marta Vivar, Vernie A Everett, Andrew W Blakers, Daniel Walter, Judy Harvey, Ruud Van Scheppingen, Sachin Surve, Jelena Muric-Nesic. Centre of Sustainable Energy Systems - Australian National University, Canberra, Australia. (785-G33) Solar Cell Models for Use in Multijunction Concentrating Optical Modeling Systems. John R. Wilcox, Alexander W. Haas, Jeffery L. Gray, Richard J. Schwartz. School of Electrical and Computer Engineering & Birck Nanotechnology Center, Purdue University, West Lafayette, IN, USA.


Area 4: Posters, Crystalline Silicon: Defect Passivation and Advanced Optics

Chair(s): Mariana Bertoni, Jan Benick (786-H27) Enhanced Angular Response of Power Conversion Efficiency for Silicon Solar Cells Utilizing a Uniformly Distributed Nano-Whisker Medium. Chia-Hua Chang1, Min-Hsiang Hsu1, Wei-Lun Chang2, Wen-Ching Sun2, Peichen Yu1. 1Department of Photonics and Institute of Electro-Optical Engineering, National Chiao Tung University, Hsinchu, Taiwan, 2Photovoltaics Technology Center, Industrial Technology Research Institute, Hsinchu, Taiwan. (787-H31) Improved Light Trapping Structure for Monocrystalline Si Solar Cells. Hyo Sik Chang, Hyun Chul Jung, Hyung Tae Kim. Korea Institute of Ceramic Engineering and Technology, Icheon, South Korea.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

184


(788-I1) Nitrogen Effect on Negative Fixed Charges of Al2O3 Passivation Film in Crystalline Si Solar Cells. Choong Hwan Shin1, Dong Wook Kwak1, Do Hyung Kim1, Dong Wha Lee1, Sung Heo2, Kyung Soo Park2, Hoon Young Cho1. 1Department of Physics, Dongguk University, Seoul, South Korea, 2Samsung Advanced Institute of Technology, Gyeonggi, South Korea. (789-I5) Comparison Between Al2O3 Surface Passivation Films Deposited with Thermal ALD, Plasma ALD and PECVD. Gijs Dingemans1, Peter Engelhart2, Robert Seguin2, Nick Terlinden1, Magda Mandoc1, Richard van de Sanden1, Erwin Kessels1. 1Eindhoven University of Technology, Eindhoven, Netherlands, 2Q-Cells, Bitterfeld-Wolfen, Germany. (790-I9) Monocrystalline Thin-Film Solar Cells from Macroporous Silicon. Marco Ernst1, Rolf Brendel1,2. 1Institut für Solarenergieforschung Hameln/Emmerthal (ISFH), Emmerthal, Germany, 2Dep. Solar Energy Research, Inst. Solid-State Physics, Leibniz University of Hannover, Hannover, Germany. (791-I13) Inkjet Structured EWT Silicon Solar Cells with Evaporated Aluminum Metallization and Laser-fired Contacts. Arne Fallisch, David Stüwe, Rainer Neubauer, Dirk Wagenmann, Roman Keding, Jan Nekarda, Daniel Biro, Ralf Preu. Fraunhofer Institute for Solar Energy Systems, Freiburg, Germany. (792-I17) Back-Contact Solar Cells in Thin Crystalline Silicon. Jerry G. Fossum1, Dabraj Sarkar1, Leo Mathew2, Rajesh Rao2, Dharmesh Jawarani2, Mark E. Law1. 1University of Florida, Gainesville, FL, USA, 2AstroWatt, Austin, TX, USA. (793-I21) High-Performance HIT Solar Cells for Thinner Silicon Wafers. Daisuke Fujishima, Hirotada Inoue, Yasufumi Tsunomura, Toshio Asaumi, Shigeharu Taira, Toshihiro Kinoshita, Mikio Taguchi, Hitoshi Sakata, Eiji Maruyama. Advanced Energy Research Center, SANYO Electric Co., Ltd., Kobe, Japan. (794-I25) N-type and P-type emitter Surface Passivation by Remote PECVD Technology. Mark A George1, Troy Shangguan1, John Madocks1, Richard Arhenkiel2. 1General Plasma, Tucson, AZ, USA, 2Colorado School of Mines, Golden, CO, USA. (795-I29) High Efficient n-type Interdigitated Back Contact Silicon Solar Cells with Screen-printed Al-alloyed Emitter. Chun Gong1,2, Emmauel Van Kerschaver1,3, Jo Robbelein1,2, Niels E. Posthuma1, Jef Poortmans1,2, Robert Mertens1,2. 1imec, Leuven, Belgium, 2Katholieke Universiteit Leuven, Leuven, Belgium, 3Solexel, Inc,, Milpitas, CA, USA. (796-I33) Thin Si Solar Cell with N Type Absorber Based on Epitaxial Lateral Overgrowth. Ruiying Hao1, C. Paola Murcia1, Kevin Shreve1, Anthony Lochtefeld2, Andrew Gerger2, Michael Curtin2, Tim Creazzo1, Allen Barnett1. 1University of Delaware, Newark, DE, USA, 2AmberWave Systems Corp, Salem, NH, USA. (797-J3) Laser Doping Technique using Continuous Wave Laser in Multi-crystalline Silicon Solar Cell Process. Mitsuhiro Hasegawa, Kenji Hirata, Takashi Saitoh, Tamaki Takayama, Tomohiro Funatani, Emi Sugimura, Shinichiro Tsujii, Ayumi Tani, Takashi Fuyuki. Nara Institute of Science and Technology, Ikoma, Japan.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


185


(798-J7) Laser Ablation and Contact Formation for Cu-plated Large Area c-Silicon Industrial Solar Cells. José Luis Hernández, Angel Urueña, Christophe Allebé, Jeff Poortmans. IMEC, Leuven, Belgium. (799-J11) Thermal Oxide, Al2O3 and Amorphous-Si Passivation Layers on Silicon. W. S. Ho1, Y.-Y. Chen1, T.-H. Cheng2, J.-Y. Chen1, J.-A. Lu1, P.-L. Huang3, C. W. Liu1,2,3,4. 1 Department of Electrical Engineering, and Graduate Institute of Electronics Engineering, National Taiwan University, Taipei, Taiwan, 2Department of Electrical Engineering, and Graduate Institute of Photonics and Optoelectronics, National Taiwan University, Taipei, Taiwan, 3National Nano Device Laboratories, Hsinchu, Taiwan, 4Center for Condensed Matter Sciences, National Taiwan University,, Taipei, Taiwan. (800-J15) Paste Development for Screen Printed mc-Si MWT Solar Cells Exceeding 17% Efficiency. Rene Hoenig1, Florian Clement1, Michael Menkoe1, Marc Retzlaff1, Daniel Biro1, Ralf Preu1, Michael Neidert2, Andreas Henning2, Carsten Mohr2, Weiming Zhang2. 1Fraunhofer Institute for Solar Energy Systems (ISE), Heidenhofstrasse 2, D-79110 Freiburg, Germany, 2W.C. Heraeus, Thick Film Division, PV Business Unit, Heraeusstrasse 12-14, D-63450 Hanau, Germany. (801-J19) Transformational Approaches to Front-face Metallization. David H Hook1, Seymen Aygun1, William J Borland2, Jon-Paul Maria1. 1North Carolina State University Department of Materials Science and Engineering, Raleigh, NC, USA, 2DuPont Microcircuit Materials, Durham, NC, USA. (802-J23) Comparison of Back Surface Field Alternatives Using Two Sided Excitation. Harold J. Hovel. IBM Corporation, Yorktown Hts., NY, USA. (803-J27) Lock-in Thermography Technique as a Reliability Tool for Silicon Solar Cell. Ali Ibrahim. Faculty of Science/physics department/Northern Border University, Arar, Saudi Arabia. (804-J31) Contacts To Silicon Using A Silver Paste Containing A Phosphorus Source. Alex S. Ionkin1, Brian M. Fish1, Zhigang Rick Li1, Feng Gao1, Lapkin Kevin Cheng1, Kurt R. Mikeska1, Charlie C. Torardi1, Mark E. Lewittes1, David H. Roach1, John G. Pepin2, William J. Borland2. 1DuPont CRD, Wilmington, DE, USA, 2DuPont MCM, RTP, NC, USA. (805-K1) Effect of Atomic Hydrogen Treatment on Passivation Quality of Aluminum Oxide for p-type Crystalline Silicon. Junpei Irikawa1, Shinsuke Miyajima1, Akira Yamada1,2, Makoto Konagai1,2. 1Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan, 2Photovoltaics Research Center, Tokyo Institute of Technology, Tokyo, Japan. (806-K5) Influence of Doping Profile of Highly Doped Regions for Selective Emitter Solar Cells. Ulrich Jäger, Sebastian Mack, Achim Kimmerle, Ralf Preu. Fraunhofer ISE, Freiburg, Germany. (807-K9) Screen-Printed Selective Emitter Silicon Solar Cells Fabricated by Ion Implantation Method. Min-Sung Jeon, Joon-Sung Lee, Hoon Oh, Myung-Ick Hwang, Do-Hyeon Kyeong, Won-Jae Lee, Eun-Chel Cho. Photovoltaic Technology Research Department, Electro-Mechanical Research Institute, Hyundai Heavy Industries Co., Ltd., Yongin-si, Gyeonggi-do, Korea.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

186


(808-K13) Surface Passivation Properties of Boron and Phosphor-Doped a-Si:H Films with Multi-Step Deposition for Si Heterojunction Solar Cells. Kwang-sun Ji1,2, Junghoon Choi1, Won-seok Choi1, Heon-Min Lee1, Donghwan Kim2. 1Solar Energy Group, Devices and Materials Lab., LG Electronics Advanced Research Institutes, Seoul, Korea, 2Meterials Science and Engineering, Korea University, Seoul, Korea. (809-K17) A Process Technology Toolbox for next Generation Large Area Crystalline Silicon Solar Cells. Joachim John1, Victor Prajapati1,2, Christophe Allebe1, Angel Uruena de Castro1,2, Jose Luis Hernandez1, Bart Vermang1,2, Aude Rothschild1, Boon Teik Chan1, Anne Lorenz1, Kris Baert1, Jef Poortmans1,2. 1IMEC, Leuven, Belgium, 2Katholieke Universiteit Leuven, Leuven, Belgium. (810-K21) Subwavelength Surface Textures for Silicon Antireflection by Ion Implantation. Nirag S Kadakia, Sebastian S Naczas, Hassaram Bakhru, Mengbing Huang. State University of New York at Albany, Albany, NY, USA. (811-K25) Efficiency Changes of Silicon Heterojunction Solar Cells on Silicon Surface Conditions. Min Gu Kang1, Sung Ju Tark1, Byung Jun Kang1, Sungeun Park1, Chan Seok Kim1,2, DaeYoung Jung2, Jeong Chul Lee2, Donghwan Kim1. 1Department of Materials Science and Engineering, Korea University, Anamdong 5ga, Seongbukku, Seoul, South Korea, 2Photovoltaic Research Center, Korea Institute of Energy Research, Jangdong, Yuseongku, Daejun, South Korea. (812-K29) Suppression of Light Induced Degradation (LID) in B-doped Cz-Si Solar Cells by Polymer SiCxNy Film. Moon Hee Kang1, Junegie Hong3, Abasifreke Ebong1, Brian Rounsaville1, Ajeet Rohatgi1,2. 1University Center of Excellence for Photovoltaics Research and Education/Georgia Institute of Technology, Atlanta, GA, USA, 2Suniva Inc., Norcross, GA, USA, 3Sixtron Advanced Materials Inc., Dorval, QC, Canada. (813-K33) H-Termination Effect on Passivation Characteristics of a-Si:H Thin Films on Silicon Wafer Surface for a-Si:H/c-Si Hetero-Junction Solar Cells. Jeong Chul Lee, Jun Yong Song, Dae Young Jung, Chan Seok Kim, Sang Hyun Park, Jun Sik Cho, Jinsoo Song. Korea Institute of Energy Research, Daejeon, South Korea. (814-L3) Corona Charging and Optical Second-Harmonic Generation Studies of the Field-Effect Passivation of c-Si by Al2O3 Films. M. M. Mandoc, M. L. C. Adams, G. Dingemans, N. M. Terlinden, M. C. M. van de Sanden, W. M. M. Kessels. Department of Applied Physics, Eindhoven University of Technology, Eindhoven, Netherlands. (815-L7) Protection from Damp-Heat Degradation of Si-SiO2 Interfaces by Overlying SiNx and Si3N4 Coatings. Xi Dai, Keith R. McIntosh. Australian National University, Canberra, Australia. (816-L11) Deep Level Transient Spectroscopy Studies of Electrically Active Centers in Solar-Grade Si. Eduard Monakhov, M. Syre, J. Mayandi, B. Olaisen, R. Søndenå, A. Holt. Institute for Energy Technology, Kjeller, Norway.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


187


(817-L15) Characterization of Boron Surface Doping Effects on PECVD Silicon Nitride Passivation. Natalita M Nursam, Klaus J Weber, Yongling Ren. The Australian National University, Canberra, Australia. (818-L19) Surface Treatment of Crystalline Silicon Realizing Extremely Low Surface Recombination Velocity Using Catalytically Generated Radicals. Keisuke Ohdaira, Motoharu Miyamoto, Koichi Koyama, Hideki Matsumura. Japan Advanced Institute of Science and Technology, Ishikawa, Japan. (819-L23) Enhancement in Efficiency of Multicrystalline Silicon Solar Cells due to Improved Plasma Texturing Process. B. Prasad, S. R. Reddy, A. K. Saxena, S. Bhattacharya, Raveesh Kumar, M. Pathak, R. K. Bhogra. BHEL-ASSCP, C/o BHEL House, Siri Fort, New Delhi-110049, India. (820-L27) Alternative Approaches for Low Temperature Front Surface Passivation of Interdigitated Back Contact Silicon Heterojunction Solar Cells. Brent Shu1, 2, Ujjwal Das1, Jesse Appel1, Brian McCandless1, Steven Hegedus1, Robert Birkmire1,2. 1Institute of Energy Conversion, Newark, DE, USA, 2Department of Physics and Astronomy, University of Delaware, Newark, DE, USA. (821-L31) Omnidirectional Antireflection of Trapezoid-corn Nanostructure on Crystalline Silicon Solar Cells. Ping chen Tseng1, Min An Tsai2, Peichen Yu1, Hao chung Kuo1. 1Department of Photonics and Institute of Electro-Optical Engineering, National Chiao-Tung University, Hsinchu, Taiwan, 2Department of Electrophysics, National Chiao-Tung University, Hsinchu, Taiwan. (822-M1) Inverted Pyramid Texturisation Without Photolithography For Multi-Crystalline Solar Cell. Der-Chin Wu1, D. Z. Dimitrov1, Ching-Hsi Lin1, Chen-Hsun Du1, Wei-Chi Hsu1, Wun-Haw Lu1, Fang-Yao Yeh1, Chung-Wen Lan1,2. 1Photovoltaics Technology Center, Industrial Technology Research Institute, Chutung, Hsinchu, Taiwan, Taiwan, 2Department of Chemical Engineering,National Taiwan University, Taipei, Taiwan. (823-M5) The Thermal Stability of Atomic-H Plasma Produced Interface Defects on Si-SiO2 Stack. Chun Zhang, Klaus.J Weber. CSES,College of Engineering and Computer Science, Canberra, Australia.


Area 6: Posters, Organic Photovoltaics: Dye Sensitized Solar Cells and Nanostructured Oxide

(824-O22) Effect of Plasma Treatment with Various Gases on Nanocrystalline TiO2 for Dye-Sensitized Solar Cell (DSSC). Ju Mi Kim, Min Jae Sin, Hyung Jin Kim, Byungyou Hong. Sungkyunkwan University, Suwon-si, South Korea. (825-O24) Improved Dye Sensitized Solar Cell Performance using Dense, Atomic Layer Deposited Titanium Oxide Compact Layer. Braden Bills, Mariyappan Shanmugam, Mahdi F. Baroughi, David Galipeau. South Dakota State University, Brookings, SD, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

188


(826-O30) Enhancement of the Photocurrent for the Dye Sensitized Tantalum-doped TiO2 Solar Cell. Jia Liu, Wei-Wei Tan, Yuan Lin. Institute of Chemistry, Beijing, China. (827-O32) Hybrid Titanium Dioxide Nanotube and Nanoparticle Structure for High Efficiency Dye Sensitized Solar Cells. Mukul Dubey, Maheshwar Shrestha, Hongshan He. South Dakota State University, Brookings, SD, USA. (828-O34) Improving Electron Transport Behavior in Titanium Dioxide Nanotube by Surface Passivation for Solar Cell Application. Maheshwar Shrestha, Mukul Dubey, Hongshan He. South Dakota State University, Brookings, SD, USA. (829-P2) Surface Passivation of Nanoporous TiO2 with a Monolayer of Hafnium Oxide for Dye Sensitized Solar Cells. Braden Bills, Mariyappan Shanmugam, Mahdi F. Baroughi, David Galipeau. South Dakota State University, Brookings, SD, USA. (830-P4) Overview of Atomic Layer Deposited Metal Oxides for Treating Nanoporous TiO2 Photoelectrode for Dye Sensitized Solar Cells. Mariyappan Shanmugam, Braden Bills, Mahdi Farrokh Baroughi. Electrical Engineering and Computer Science Department, South Dakota State University, Brookings, SD, USA. (831-P6) Synthesis of TiO2 Nanodendrite for Dye-sensitized Solar Cell Application. Wen-Ping Liao, Jih-Jen Wu. National Cheng Kung University, Tainan, Taiwan. (832-P8) Dye Sensitized Solar Cells with TiO2 Nanotube Spacer. Jungmin Lim, Heejin Nam, Yimhyun Jo, Yongseok Jun. UNIST, Ulsan, Korea. (833-P10) The Fabrication and Performance of Nanoporous TiO2/SnO2 Electrodes with Half Hollow Sphere Structure for Dye Sensitized Solar Cell. Bak Yu-Rim, Hwang Moon-Jin, Ryu Kwang-Sun. University of Ulsan, Ulsan, South Korea. (834-P12) Electron Transport in Dye Sensitized Solar Cells with TiO2/ZnO Core-Shell Photoelectrode. Mariyappan Shanmugam, Braden Bills, Mahdi Farrokh Baroughi, David Galipeau. Electrical Engineering and Computer Science Department, South Dakota State University, Brookings, SD, USA. (835-P14) Characteristic Study of ZnO Film as an Anode for the Dye-Sensitized Solar Cells. Wei-Yuan Tseng1, Fu-Tsai Hwang1, Chuan-Jung Lin1, Chien-Chung Hsu2, Horng-Show Koo2. 1Department of electro-optical Engineering, National United University, Miao-Li, Taiwan, 2Department of Optoelectronic System Engineering, Minghsin University of Science and Technology, Hsinfong, Hsinchu, Taiwan. (836-P16) Zinc Oxide Nanostructured Material for Dye-Sensitized Solar Cells. G. REY1,2, N. KARST1, V. CONSONNI1,2, C. JIMENEZ1, B. DOISNEAU1, L. RAPENNE1, C. TERNON2, D. BELLET1. 1Laboratoire des Materiaux et Génie Physique, Grenoble, France, 2Laboratoire des Technologies de la Microélectronique, Grenoble, France. (837-P18) Dye Sensitized Solar Cells Fabricated on ZnO Nanorod Assisted Electrode. Yimhyun Jo, Yongseok Jun. UNIST, Ulsan, South Korea.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


189


(838-P20) Nanowire Dye-Sensitized Solar Cell with a Novel Light-Scattering Layer. Wen-Pin Liao, Jih-Jen Wu. National Cheng Kung University, Tainan, Taiwan. (839-P22) The Effect of Vertically Oriented ZnO Nanowires and the Surface Modification on the Performance of Inverted Hybrid Organic Photovoltaic. Dong Chan Lim1, Won-Hyun Shim1,2, Mi Yeong Park1, Young Tae Kim1,2, Sun Young Park1,3, Dong Suck Park1, Sung-Woo Cho1, Yang Do Kim2, Jae Wook Kang1, Yongsoo Jeong1, Kyu Hwan Lee1. 1Korea Institute of the Materials Science (KIMS), Changwon, South Korea, 2Pusan National University, Busan, South Korea, 3Pukyong National University, Buan, South Korea. (840-P24) Three-Dimensional ZnO Nanodendrite/Nanoparticle Composite Solar Cells. Chun-Te Wu, Jih-Jen Wu. National Cheng Kung University, Tainan, Taiwan. (841-P30) Superimposed RF/DC Magnetron Sputtering of Transparent Ga:ZnO with High Conductivity for Photovoltaic Contacts Applications. Ajaya K. Sigdel1,2, Yi Ke3, N. Edwin Widjonako4, Dana C. Olson1, Matthew T. Lloyd1, John D. Perkins1, Maikel F.A.M. van Hest1, Sean E. Shaheen2, Thomas Gennett1, David S. Ginley1, Joseph J. Berry1. 1National Renewable Energy Laboratory, Golden, CO, USA, 2Department of Physics and Astronomy, University of Denver, Denver, CO, USA, 3Colorado School of Mines, Golden, CO, USA, 4Department of Physics, University of Colorado, Boulder, CO, USA. (842-P32) Fabrication of Dye Sensitized Solar Cell with Surface Textured Substrates. Linda Y. Chen1, Maan Alkaisi1, Mei-Yi Liao2. 1University of Canterbury, Christchurch, New Zealand, 2National Nano Device Laboratory, Tainan, Taiwan. (843-P34) Hafnium (IV) and Zirconium (IV) Porphyrinato and Phthalocyaninato Diacetate Complexes as New Dyes for Solar Cell Devices. Ivana Radivojevic1, Matthew Sfeir2, Chang-Yong Nam2, Benjamin P. Burton-Pye1, Alexander Falber1, Charles T. Black2, Charles Michael Drain1. 1Department of Chemistry & Biochemistry, Hunter College and Graduate Center of the City University of New York, New York City, NY, USA, 2Center for Functional Nanomaterials, Brookhaven National Laboratory, Upton, NY, USA. (844-Q2) Fabrication of TCO-less Dye-Sensitized Solar Cells with Ti Electrodes by Electron-Beam Evaporation Process. Yun-Gi Kim, Choung-Hwan Shim, Hyun-Gyu Kim, Dong-Hyun Kim, Hae-June Lee, Chung-Hoo Park, Ho-Jun Lee. Department of Electrical Engineering, Pusan National University, Busan, Korea. (845-Q4) Development of Solid Polymeric Electrolyte for DSSC Device. Kuei-Fu Chen1, Chien-Hung Liu1, Jia-Hua Lee2, Fu-Rong Chen1. 1Engineering and System science, National Tsing Hua University, Hsinchu, Taiwan, 2Industrial Technology Research Institute, Hsinchu, Taiwan. (846-Q6) Chemically Linking Conjugated Polymers onto Nanostructure TiO2 for Solar Cell Applications. Tingting Xu1, Jing Li1, Yu Xie1, Heather Rohwer2, James D. Hoefelmeyer2, Qiquan Qiao1. 1South Dakota State University, Brookings, SD, USA, 2The University of South Dakota, Vermillion, SD, USA.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS

190


(847-Q8) Co-assembly of Titania Precursor and Water-Soluble Polythiophene into Mesostructured Photovoltaic Films. Tamar Segal-Peretz1, Gitti L. Frey2. 1The Norman Seiden program for nanoscience and nanotechnology, Technion – Israel Institute of Technology, Haifa, Israel, 2Department of Materials Engineering, Technion – Israel Institute of Technology, Haifa, Israel. (848-Q10) Enhanced Carrier Collection and Light Harvesting of Polymer Solar Cells Using Embedded Indium-Tin-Oxide Nano-Electrodes. Min-Hsiang Hsu1, Chia-Hua Chang1, Jen-Hsien Huang2, Chih-Wei Chu2, Peichen Yu1. 1Department of Photonics, National Chiao-Tung University, Hsinchu, Taiwan, 2Research Center for Applied Sciences, Academia Sinica, Taipei, Taiwan. (849-Q12) Tailoring CuPc Nanostructures via Glancing Angle Deposition. Jaron G Van Dijken1, Al Lalany1, Michael D Fleischauer2, Michael J Brett1,2. 1Electrical & Computer Engineering, University of Alberta, Edmonton, AB, Canada, 2NRC National Institute for Nanotechnology, Edmonton, AB, Canada. (850-Q14) Detailed Balance Limit for DBA Solar Cell Efficiency. Evgeny Morozov, Pavel Khokhlov, Pavel Lazarev. Cryscade Solar Ltd., South San Francisco, CA, USA. (851-Q16) Organic Solar Cell Using Semi-Transparent High Work-Function Metal as Anodes. Soniya D Yambem, Amrita Haldar, Kang-Shyang Liao, Seamus A Curran. University of Houston, Houston, TX, USA. (852-Q18) Large-Area Organic Solar Cells with Metal sub-Electrode on ITO Anode. Jae-Wook Kang, Sun-Young Park, Do-Geun Kim, Jong-Kuk Kim. Korea Institute of Materials Science (KIMS), Changwon, Korea. (853-Q20) Resistive Power Loss of Indium-Tin-Oxide in Organic Solar Cells. Satish Sankaralingam. Birla Institute of Technology and Science, Pilani, Jhunjhunu, India. (854-Q22) A New Aspect for Light Collection in Conventionally Designed High-Efficiency Organic Photovoltaics. Nigel J. Alley1,2, Sampath Dias1, Kang-Shyang Liao1, James R. Glennie1, Seamus A. Curran1. 1Institute for NanoEnergy, Department of Physics, University of Houston, Houston, TX, USA, 2School of Physical Sciences, Dublin City University, Glasnevin, Dublin 9, Ireland.

WED

NES

DA

Y P

OS

TER

PR

ES

EN

TA

TIO

NS


191


THURSDAY JUNE 24POSTER PRESENTATIONS



Area 1: Posters, Fundamentals & New Concepts Chair(s): Ryne Raffaelle, Yoshitaka Okada, Nicholas Ekins-Daukes (855-A3) Fabrication of PECVD Grown n-i-p Silicon Nanowire Solar Cells. Michael M. Adachi, Karim S. Karim. Department of Electrical and Computer Engineering, University of Waterloo, Waterloo, ON, Canada. (856-A6) Determination of a Sb Composition in InAs/GaAsSb for a Negligible Valence Band Offset. Keun-Yong Ban1, Darius Kuciauskas2, Som N. Dahal1, Stephen P. Bremner3, Christiana B. Honsberg1. 1Department of Electrical Engineering, Arizona State University, Tempe, AZ, USA, 2National Renewable Energy Laboratory, Golden, CO, USA, 3School of Photovoltaic and Renewable Energy Engineering, University of New South Wales, Sydney, Australia. (857-A9) Carbon Nanotube-Composite Wafer Bonding for Ultra-High Efficiency Multijunction Solar Cells. Andreea Boca1, Joseph C. Boisvert1, Daniel C. Law1, Shoghig Mesropian1, Nasser Karam1, Evgeniya Turevskaya2, Patrick Mack2, Paul Glatkowski2. 1Spectrolab, Inc., Sylmar, CA, USA, 2Eikos, Inc., Franklin, MA, USA. (858-A12) Growth and Characterization of InGaN for Photovoltaic Devices. Chris Boney1,2, Ivan Hernandez1, Rajeev Pillai2, David Starikov1,2, Abdelhak Bensaoula3, Mohamed Henini4, Robert Kudrawiec5, Marcin Syperek5, Jan Misiewicz5. 1Integrated Micro Sensors, Inc, Houston, TX, USA, 2Dept. of Physics, University of Houston, Houston, TX, USA, 3Depts. of Physics and Electrical Engineering, University of Houston, Houston, TX, USA, 4School of Physics & Astronomy, University of Nottingham, Nottingham, United Kingdom, 5Institute of Physics, Wrocław University of Technology, Wroclaw, Poland. (859-A15) Amorphous GaN1-xAsx Alloys for Multi-junction Solar Cells. Robert J. Broesler1,2, Kin M. Yu1, Sergi V. Novikov3, Zuzanna Liliental-Weber1, Eugene E. Haller1,2, Wladek Walukiewicz1, C Thomas Foxon3. 1Materials Science Division, Lawrence Berkeley National Laboratory, Berkeley, CA, USA, 2Department of Materials Science and Engineering, University of California-Berkeley, Berkeley, CA, USA, 3School of Physics and Astronomy, University of Nottingham, Nottingham, United Kingdom. (860-A18) Design of a Functional Rare Earth Oxide Upconversion Layer for Bulk Silicon Cells. Andrew Clark, David Williams, Erdem Arkun, Scott Semans, Aleta Jamora. Translucent Inc, Palo Alto, CA, USA. (861-A21) A Rare Earth Oxide Enabled Monolithic Three-Terminal Si-SiGe Tandem Solar Cell. Erdem Arkun, Robin Smith, Gary Vosters, Andrew Clark. Translucent Inc, Palo Alto, CA, USA.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS

192


(862-A24) Fabrication of Dye Sensitized Solar Cell using Polyaniline Nanofibers as Counter Electrode. Sadia Ameen, Chul Gi Jo, Young Soon Kim, Hyung Shik Shin. Chonbuk National Uinversity, Jeonju, Korea. (863-A31) CdSe Thin Film Solar Cells Utilizing a Nanostructured Back Contact. Dennis J. Flood. Vanguard Solar, Inc., Oberlin, OH, USA. (864-A34) Fabrication and Characterization of Electrodeposited Cu2O p-n Homojunction Solar Cells. Kunhee Han1, Xiaofei Han2, Meng Tao1. 1University of Texas at Arlington, Dept. of Electrical Engineering, Arlington, TX, USA, 2University of Texas at Arlington, Dept. of Material Science and Engineering, Arlington, TX, USA. (865-B3) Silicon Quantum Dots in an Oxide Matrix for Third Generation Photovoltaic Solar Cells. Lihao Han, Jing Wang. Institute of Microelectronic, Tinghua University, Beijing 10084, China. (866-B6) GaP Epitaxial Films for Si-based Multi-junction Solar Cells Grown by Liquid Phase Epitaxy. Susan R Huang1, Xuesong Lu2, Allen Barnett2, Robert L. Opila1. 1Department of Materials Science and Engineering, University of Delaware, Newark, DE, USA, 2Department of Electrical and Computer Engineering, University of Delaware, Newark, DE, USA. (867-B9) Si Quantum Dot-Sensitized Solar Cells using Si Nanoparticles Produced by Plasma CVD. Y. Kawashima1, K. Nakahara1, T. Matsunaga1, H. Sato1, K. Koga1, M. Shiratani1, M. Kondo2. 1Kyushu Univ., Fukuoka, Japan, 2AIST, Tsukuba, Japan. (868-B12) Technical Challenges and Benefits of Using Nanowires in Photovoltaic Devices. Maha Khayyat, Brent Wacaser, Mark Reuter, Devendra Sadana. IBM, Yorktown Heights, NY, USA. (869-B15) Silicon Nanowire-Schottky Solar Cell by Liquid Processes. Joondong Kim1, Ju-Hyung Yun1, Chang-Soo Han1, Yong Jae Cho2, Jeunghee Park2, Yun Chang Park3. 1Korea Institute of Machinery and Materials (KIMM), Daejeon, South Korea, 2Korea University, Jochiwon, South Korea, 3National Nanofab Center, Daejeon, South Korea. (870-B18) Semiconducting β-FeSi2 for Low-Cost and High Conversion Efficiency Photovoltaics. Abhishek Kumar1, 2, Lalit K. Verma2, Hyunsoo Yang2, Aaron Danner2, Dongzhi Chi1, Charanjit S. Bhatia1, 2. 1Institute of Materials Research and Engineering (IMRE), Singapore 117602, Singapore, 2National University of Singapore, Singapore 117576, Singapore. (871-B21) Fabrication of Heterojunction Thin-Film Solar Cells with Cu2O and ZnO-Nanowire Structure. Yun Seog Lee1,2, Jaebum Joo3,4, Mariana I. Bertoni1,2, Joseph Jacobson1,3,4, Tonio Buonassisi1,2. 1Department of Mechanical Engineering, Massachusetts Institute of Technology, Cambridge, MA, USA, 2Laboratory for Manufacturing Productivity, Massachusetts Institute of Technology, Cambridge, MA, USA, 3The Center for Bits and Atoms, Media Laboratory, Massachusetts Institute of Technology, Cambridge, MA, USA, 4Department of Materials Science and Engineering, Massachusetts Institute of Technology, Cambridge, MA, USA.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS


193


(872-B24) Polymer – CuInS2 Hybrid Solar Cells Obtained by Different In-Situ Formation Routes. Eugen Maier1, Wernfried Haas2,3, Thomas Rath1,2, Robert Saf1, Ferdinand Hofer3, Franz Stelzer1, Dieter Meissner4, Gregor Trimmel1,2. 1Institute for Chemistry and Technology of Materials (ICTM), Graz University of Technology, Graz, Austria, 2Christian Doppler Laboratory for Nanocomposite Solar Cells, Graz, Austria, 3Institute for Electron Microscopy of the TU Graz (FELMI), Graz, Austria, 4Department of Materials Science, Tallinn University of Technology, Tallinn, Estonia. (873-B31) Moving Past 2.0 eV: Engineered ZnSe-GaAs Alloys for Multijunction Solar Cells. Kyle H Montgomery, Jerry M Woodall. School of Electrical and Computer Engineering & Birck Nanotechnology Center, West Lafayette, IN, USA. (874-B34) Optical Characterization and Modeling of the Lead Chalcogenide Quantum Dot Solar Cell: A Rational Approach to Device Development and Multiple Exciton Generation. Octavi E Semonin1, Sukgeun Choi2, Joseph M Luther2, Matthew C Beard2, Arthur J Nozik2. 1University of Colorado, Boulder, CO, USA, 2National Renewable Energy Laboratory, Golden, CO, USA. (875-C3) First-principles Study of Cu2ZnSnS4 as Thin-film Solar Cell Absorber. Su-Huai Wei1, Shiyou Chen2,3, Xingao Gong2, Aron Walsh1,3. 1National Renewable Energy Laboratory, Golden, CO, USA, 2Fudan University, Shanghai, China, 3East China Normal University, Shanghai, China, 4University College London, London, United Kingdom. (876-C6) Modeling of InGaN PIN Solar Cells with Defect Traps and Polarization Interface Charges. Yegao Xiao, Zhiqiang Li, Michel Lestrade, Zhanming S. Li. Crosslight Software Inc, Burnaby, BC, Canada. (877-C9) InGaAs/GaAsP Strain-Compensated Superlattice Solar Cells for Enhanced Spectral Response. Yunpeng Wang1, Yu Wen1, Sugiyama Masakazu 2, Yoshiaki Nakano1. 1Research Center for Advanced Science and Technology, the University of Tokyo 4-6-1 Komaba, Meguro-ku, Tokyo, Japan, 2Department of Electrical Engineering and Information Systems, School of Engineering, the University of Tokyo, Tokyo, Japan.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS

194



Area 2: Posters, CIGS & CdTe: CIGS II Chair(s): Tokio Nakada, Jim Sites (878-C23) Advantages of Indium Sulphide as an Alternative Buffer Layer in CIGS Solar Cells from Numerical Analysis. Nowshad Amin1,2,3, Mohammad I Hossain1, Puvaneswaran Chelvanathan1. 1Department of Electrical, Electronics and System Engineering, National University of Malaysia, Bangi, Malaysia, 2Solar Energy Research Institute, National University of Malaysia, Bangi, Malaysia, 3Center of Excellence for Research in Engineering Materials (CEREM), College of Engineering, King Saud University, Riyadh, Saudi Arabia. (879-C26) Cryogenic Cathodoluminescence from CuxAg1-xInSe2 Thin Films. Angel R Aquino1, Scott A Little2, Sylvain Marsillac2, Angus Rockett1. 1Department of Materials Science and Engineering, University of Illinois, Urbana, IL, USA, 2Center for Photovoltaics Innovation and Commercialization, University of Toledo, Toledo, OH, USA. (880-C29) Preparing of CIGS Nanoparticles using One-Step Synthesis. Eun-Jin Bae, Ki-Bong Song, Jung-Min cho, Jeong-Dae Suh, Chang-Woo Ham. Electronics and Telecommunications Research Institute,138 Gajeongno, Yusung-Gu, Daejeon, South Korea. (881-C32) Ultrasonically Sprayed Zinc Sulfide Buffer Layers for Cu(In,Ga)(S,Se)2 Solar Cells. Carolin Fella, Stephan Buecheler, Adrian Chirila, Dominik Guettler, Alexander Uhl, Ayodhya Nath Tiwari. Laboratory for Thin Films and Photovoltaics, Empa – Swiss Federal Laboratories for Materials Testing and Research, Duebendorf, Switzerland. (882-D1) Fabrication and Characteristics of CuInSe2/CuIn(SexS1-x)2 Structure by the Sulfurization of the CuInSe2 Thin Film. Jhe Wei Guo, Tung Po Hsieh, Chung Shin Wu, Jen Chuan Chang, Shu Chun Hsu, Pei Sun Sheng, Chia Chih Chuang. Industrial Technology Research Institute, 195 Chung Hsing Road, Sec. 4 Rm. 827, Bldg. 52, Hsin Chu, Taiwan. (883-D4) The Thickness Effect of SiOx Layer in CIGS Thin-Film Solar Cells Fabricated on Stainless-Steel Substrate. Y. D. Chung, D. H. Cho, W. S. Han, N. M. Park, K. S. Lee, S. Y. Oh, J. Kim. ETRI, Daejeon, Korea. (884-D7) Room Temperature Non-vacuum Preparation of Nanocrystalline CuInSe2 Employing Aqueous Solvents. Christopher L. Exstrom1, Scott A. Darveau1, Matt. A. Ingersoll1, Matthew R. Jensen1, Chelsey Cook1, Laura E. Slaymaker1, Rodney J. Soukup2, Natale J. Ianno2. 1University of Nebraska at Kearney, Kearney, NE, USA, 2University of Nebraska-Lincoln, Lincoln, NE, USA. (885-D10) Low-Temperature Indium Molybdenum Oxide as a Window Layer in CIGS Photovoltaic Devices. Alex D DeAngelis, Jess Kaneshiro, Nicolas Gaillard, Yuancheng Chang, Jeremy Kowalcyzk, Stewart A Mallory, Eric L Miller. University of Hawaii, Honolulu, HI, USA.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS


195


(886-D13) Thermal Degradation and Light Capture Performance of CuInGaSe2 (CIGS) and c-Si Photovoltaic Devices. Rebekah K. Feist, Michael Mills, Steve Rozeveld, Charlie Wood, Kirk Thompson. The Dow Chemical Company, Midland, MI, USA. (887-D16) Solar Cells via Selenization of CuInS2 Nanocrystals: Effect of Synthesis Precursor. Grayson M Ford, Qijie Guo, Rakesh Agrawal, Hugh W Hillhouse. Purdue University, West Lafayette, IN, USA. (888-D19) Influence of NaF Incorporation During CIGS Evaporation on Microstructure and Photovoltaic Performance. D. Guettler1, A. Chirila1, A. Uhl1, X. Fontane2, V. Izquierdo-Roca2, L. Calvo-Barrio2,3, A. Pérez-Rodríguez2,4, J. R. Morante2,4, A. N. Tiwari1. 1Laboratory of Thin Films and Photovoltaics, Empa – Swiss Federal Laboratories for Materials Testing and Research, Duebendorf, Switzerland, 2M-2E/XaRMAE/IN2UB, Departament d’Electrònica, Universitat de Barcelona, C. Martí i Franquès 1, Barcelona, Spain, 3Lab. Anàlisis de Superficies, SCT, Univ. Barcelona, Barcelona, Spain, 4IREC, Catalonia Institute for Energy Research, Barcelona, Spain. (889-D22) Wide-bandgap (AgCu)(InGa)Se2 Absorber Layers Deposited by Three-stage Co-evaporation. Gregory M. Hanket, Jonathan H. Boyle, William N. Shafarman. Institute of Energy Conversion, University of Delaware, Newark, DE, USA. (890-D25) Field Assisted Simultaneous Synthesis and Transfer FASST® Method Used in Conjunction with Liquid Precursors to Produce CIGS Solar Cells. Peter A. Hersh1, Calvin J. Curtis2, Maikel F.A.M. van Hest2, Susan E. Habas2, Alexander Miedaner2, David S. Ginley2, Billy J. Stanbery1, Louay Eldada1. 1Heliovolt, Austin, TX, USA, 2NREL, Golden, CO, USA. (891-D28) Characterization of ZnO Thin Films Prepared by Various Wet Processes as Buffer Layers for CIGS Solar Cells. Chia-Hua Huang, Yueh-Lin Jan, C.Y. Ding. Department of Electrical Engineering, National Dong Hwa University, Hualien, Taiwan. (892-D31) Synthesis and Characterization of Cu(In,Ga)Se2 Nanoparticles and Thin-Films Solar Cells. Ah Reum Jeong, Ran Hee Shin, Nu Ri Lee, William Jo. Ewha Womans University, Seoul, South Korea. (893-D34) Water Vapor Delivery for CIGSe and Other Thin Film Vacuum Processes. Jeffrey J. Spiegelman1, Said Boumsellek2. 1RASIRC, San Diego, CA, USA, 2Implant Sciences Corp, San Diego, CA, USA. (894-E3) Study on Real Out-Door Performance Characteristics of Polycrystalline Si and CIGS Solar Modules. Byoung Dong Kim. Samsung Electronics, Yongin, South Korea. (895-E6) Preparation of β-Cu(In,Ga)3Se5 Thin-Films for Wide Band Gap Absorber for Top Cell in CIGS Tandem Structure. Ji Hye Kim, Young Min Shin, Byung Tae Ahn. Department of Material Science and Engineering, Korea Advanced Institute of Science and Technology, Daejeon 305-701, South Korea.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS

196


(896-E9) Growth of Sprayed CIS Film and Solar Cell Application. Dong-Yeup Lee1, Hyesun Yoo1, Ki-Bong Song2, Jae Ho Yun3, JunHo Kim1. 1University of Incheon, Incheon, South Korea, 2ETRI, Daejeon, South Korea, 3KIER, Daejeon, South Korea. (897-E12) CIGS Thin Films Fabricated by DC Sputtering using CIGS Quaternary-Alloyed Target. Tae-Won Kim1, Jae-Soek An1, Young-Baek Kim2, Gi-Soek Hoe1, Kwang-Young Kim1. 1Korea Institute of Industrial Technology, Gwangju, South Korea, 2Selcos, Gwangju, South Korea. (898-E15) CIS Low-Cost Thin-Film Solar Cells made from Elemental Metallic Nanoparticles: Comparison of Selenisation Parameters. Ines Klugius, Catherin Gemmel, Aina Quintilla, Veronika Haug, Erik Ahlswede. Zentrum für Sonnenenergie- und Wasserstoff-Forschung Baden-Württemberg (ZSW), Stuttgart, Germany. (899-E18) CIGS Thin Film Solar Cell Modules on Low-cost PV Glass Substrates. JinWoo Lee1, SeungYup Lee1, HoGun Cho1, HeeKyoung Yoon1, Jae Ho Yun2, SeHan Kwon1, WoongSik Kim1, JooWon Lee1. 1LG Innotek, Ansan, Korea, 2Korea Institute of Energy Research, Daejeon, Korea. (900-E21) Effect of Substrate Temperature on the Optical Properties of Polycrystalline CuInSe2 Thin Films. Jian Li1,2, Ingird Repins1, Bobby To1, Lorelle Mansfield1, Sukgeun Choi1, Miguel Contreras1, Fred Lewis Terry Jr.2, Dean Levi1. 1National Renewable Energy Lab, Golden, CO, USA, 2University of Michigan, Ann Arbor, MI, USA. (901-E24) Cu(In, Ga)Se2 Thin-film Solar Cells Grown at Low Temperatures on Polyimides. Lorelle M Mansfield, Ingrid L Repins, Matthew R Young, Jian V Li, Bobby To, Stephen Glynn, Clay DeHart. National Renewable Energy Laboratory, Golden, CO, USA. (902-E27) Grain Boundary Recombination Activity in Cu(In,Ga)Se2 Solar Cells with Ion-Polished Flat Surface. Takashi Minemoto, Yoichi Wakisaka, Hideyuki Takakura. Ritsumeikan University, Kusatsu, Japan. (903-E30) Selenization Pathways to 2SSS CIGS Manufacturing. Don L Morel, Chris S Ferekides, Ryan Anders, Keshavanand Jayadevan. University of South Florida, Tampa, FL, USA. (904-E33) Investigation of Differences between High and Low Efficiency CIGS Solar Cell Structures using Surface Analytical Techniques. Gary R Mount1, Temel Buyuklimanli2, Roger Michel3, John Moskito1, Steve Robie1, Udit Sharma1, Greg Strossman1, Larry Wang1. 1Evans Analytical Group, Sunnyvale, CA, USA, 2Evans Analytical Group, East Windsor, NJ, USA, 3RM, Redmond, WA, USA. (905-F2) Optimization Study of Copper Precursors for High Quality CuInSe2 Nanoparticles by Wet Chemical Route. Umme Farva1, Jooyoung Lee2, Jun Young Park1, Rangarajan Krishnan2, Timothy Anderson2, Chinho Park1. 1Yeungnam University, Gyeongsan, South Korea, 2University of Florida, Gainesville, FL, USA.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS


197


(906-F5) A Study of the Structure and Electrical Properties of CuInSe2/Cu-Substrate. Soon-Yong Park, Eun-Woo Lee, Sang-Hwan Lee, Sang-Wook Park, Jae Sung Han, Chan-Wook Jeon. Yeungnam University, Gyeongsan-si, Kyungsangbuk-do, Korea. (907-F8) All-Laser Scribing for Thin-Film CuInGaSe2 Solar Cells. F.J. John Pern1, Lorelle Mansfield1, Stephen Glynn1, Clay DeHart1, Suwas Nikumb2, Craig Dinkel2, Mathew Rekow3, Richard Murison3, Tullio Panarello3, Corey Dunsky3. 1National Center for Photovoltaics, National Renewable Energy Laboratroy, Golden, CO, USA, 2National Research Council of Canada, London, ON, Canada, 3PyroPhotonics Lasers, Inc., Campbell, CA, USA. (908-F10) Manufacturing Ramp-Up of Flexible CIGS PV. S. Wiedeman1, S. Albright1, J. S. Britt1, U. Schoop1, S. Schuler2, W. Stoss1, D. Verebelyi1. 1Global Solar Energy, Inc., Tucson, AZ, USA, 2Global Solar Energy, Inc., Berlin, Germany.


Area 4: Posters, Crystalline Silicon: Device Fabrication and Manufacturing

Chair(s): Weiming Zhang, Stuart Bowden (909-H28) Novel Front Metal Contact Patterning Scheme for c-Si Solar Cells. A.P Sastry 1, Vikrant Chaudhari2, Chetan Solanki3. 1Department of Energy Science and Engineering, Indian Institute of Technology Bombay, Powai, Mumbai, India, 2Department of Energy Science and Engineering, Indian Institute of Technology Bombay, Powai, Mumbai, India, 3Department of Energy Science and Engineering, Indian Institute of Technology Bombay, Powai, Mumbai, India. (910-H32) Interaction Between Post Wire Saw Cleaning And The Subsequent Cell Fabrication Saw Damage Etch And Texturing Process. George Allardyce1, Robert Barr2, Raymond Chan2, Matt Moynihan2, Corey O’Connor2, Tony Ridler1. 1Dow Electronic Materials, Coventry, United Kingdom, 2Dow Electronic Materials, Marlborough, MA, USA. (911-I2) Characterizing Segmented Co-firing Furnace for Contact Formation. Tianming Bao, Yan Guo, Lihua Li, Frank Bottari. BTU International, Billerica, MA, USA. (912-I6) New Printing Pattern Design and Processing of MWT Solar Cells for Pilot-Line. Sung-Yu Chen, Chao-Ping Huang, Bing-Cyun Chen, Shih-Wei Hung, Wei-Chih Hsu, Chen-Hsun Du, Der-Chin Wu. Photovoltaics Technology Center, Industrial Technology Research Institute, Hsinchu, Taiwan. (913-I10) Surface Structure of Mono-Crystalline Silicon Wafers Produced by Diamond Wire Sawing and by Standard Slurry Sawing before and after Etching in Alkaline Solutions. Arve Holt1, Annett Thøgersen1, Carsten Rohr2, Jan-Inge Bye1, Geir Helgesen1, Ørnulf Nordseth1, Sten Aksel Jensen2, Lasse Norheim2, Øyvind Nielsen2. 1Institute for Energy Technology (IFE), P.O. Box 24, NO-2027, Kjeller, Norway, 2NorSun AS, Sommerrogaten 13-15, NO-0255, Oslo, Norway.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS

198


(914-I14) Industrial Realization of a Novel High-Throughput Belt-Furnace Diffusion for High Efficiency Silicon Solar Cells. Min-Hung Hsu, Yi-Fan Lai, Che-Chang Tsao, Kuo-Chen Hsiang, Yen-Chang Chen, Cheng-Wen Kuo. Top Green Energy Technologies Inc., Miaoli County, Taiwan. (915-I18) Understanding Metallic and Ionic Contamination in Photovoltaic Wet Chemistries from Chemical Delivery Systems. Michael W Johnson. Entegris, Chaska, MN, USA. (916-I22) Thermal Profiling of Silicon Solar Cells during the Metallization Process. Casey Kazmierowicz1, Umesh Kumar2, Ed Graddy2. 1KIC, 16120 Bernardo Center Dr., San Diego, CA, USA, 2Ferro Corporation, 1395 Aspen way, Vista, CA, USA. (917-I26) High Efficient Si Light-Emitting Diodes and Textured-Si Solar Cells with Obvious Photonic Crystal Effect in Nano-Surface Trench Structure, Manufactured and Integrated by Advanced CMOS Semiconductor Process. M. H. Liao2, W.-C. Wang1, H. R. Tsai2, S. T. Chang1. 1NCHU, Taipei, Taiwan, 2TSMC, Taipei, Taiwan. (918-I30) The Investigation of the Optimal Si-SiGe Hetero-Structure Thin-Film Solar Cell with the Theoretical Calculation and Quantitative Analysis. M. H. Liao1, W. S. Ho2, Y.-Y. Chen2, S. T. Chang3. 1TSMC, Taipei, Taiwan, 2NTU, Taipei, Taiwan, 3NCHU, Taipei, Taiwan. (919-I34) Characterization of Selective-Emitter Solar Cells Consists of Laser Opened Window and Subsequently Screen-Printed Electrodes. Ching-Hsi Lin1, Shih-Peng Hsu1, Jia-Jhe Liou1, 2, Chia-Pin Chuang1, Wen-Haw Lu1, Wei-Lun Chang1. 1Industrial Technology Research Institute, Chutung, Hsinchu, Taiwan, 2National Taiwan Ocean University, Keelung, Taiwan. (920-J4) Purified Steam for Industrial Thermal Oxidation Processes. Sebastian Mack1, Daniel Biro1, Andreas Wolf1, Alexandra Walczak1, Jeffrey Spiegelman2, Ralf Preu1. 1Fraunhofer ISE, Freiburg im Breisgau, Germany, 2RASIRC, San Diego, CA, USA. (921-J8) All Screen-Printed Industrial n-Type Czochralski Silicon Solar Cells with Aluminium Rear Emitter and Selective Front Surface Field. Karsten Meyer1, Hans-Joachim Krokoszinski1, Christian Schmiga2, Martin Hermle2, Stefan Glunz2. 1Bosch Solar Energy, Erfurt, Germany, 2Fraunhofer Institute for Solar Energy Systems (ISE), Freiburg, Germany. (922-J12) Development of No-Rinse Screen Printable Etch Paste for Contact Via in Dielectric Films. Rohit Mishra, Zhen-Hua Zhang, Hsiu-Wu Guo, Prabhat Kumar, Hemant Mungekar, Michael Stewart, Timothy Weidman, Suketu Parikh, Steve Paak. Applied Materials, Inc., Santa Clara, CA, USA. (923-J16) Low-Cost Solar Grade Silicon: Purification and Consolidation of Silicon Fines from Wafering. Lorenza Moro1, Brian Xie1, Jordi Perez1, Kai Lau1, Angel Sanjurjo1, Lawrence H. Dubois2, Ben Lochtenberg2. 1SRI International, Menlo Park, CA, USA, 2ATMI, Danbury, CT, USA. (924-J20) Analysis of Internal Reflectivity of Silicon ELO PV Cells Obtained by IPE. Jan.M. Olchowik, K. Cieslak, S. Gulkowski. Technical University of Lublin, Lublin, Poland.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS


199


(925-J24) Interdigitated Rear Contact Solar Cells with Amorphous Silicon Heterojunction Emitter. BJ O’Sullivan1, T Bearda1, Y Qiu1, J Robbelein2, C Gong2, N.E. Posthuma1, I Gordon1, J Poortmans1. 1IMEC, Leuven, Belgium, 2Dept of Electrical Engineering, Katholieke Universiteit Leuven, Leuven, Belgium. (926-J28) Laser Process Optimization for Improving Emitter Wrap Through Drilling Rates. Henrikki Pantsar1, Hans J. Herfurth1, Stefan Heinemann1, Mathew Rekow2, Richard Murison2. 1Fraunhofer USA, Inc., Plymouth, MI, USA, 2Pyrophotonics Lasers, Inc., Montreal, QC, Canada. (927-J32) Development and Characterization of Advanced Process Technologies for the Fabrication of Crystalline Si Solar Cells. Satyavolu S. Papa Rao, Kate Fisher, Deborah Neumayer, Qiang Huang, Keith Kwietniak, Jun Liu, James Vichiconti, Jakub Nalaskowski, Joseph Newbury, Adam Pyzyna, Stephen Rossnagel, George Totir, Nicholas Fuller. IBM T.J. Watson Research Center, Yorktown Heights, NY, USA. (928-K2) Silicon Ink Selective Emitter Process: Optimization of the Ink Finger Width for Short Wavelength Response. Dmitry Poplavskyy, Giuseppe Scardera, Malcolm Abbott, Andreas Meisel, Xiao Chen, Sunil Shah, Elizabeth Tai, Mason Terry, Francesco Lemmi. Innovalight, Sunnyvale, CA, USA. (929-K6) Comparison of the Intrinsic Amorphous Silicon Interface Buffer Layers for Silicon Heterojunction Solar Cells Deposited with Different Plasma Deposition Techniques. Damian Pysch, Christoph Meinhardt, Jan Becker, Martin Bivour, Karin Zimmermann, Christian Schetter, Martin Hermle, Stefan Glunz. Fraunhofer, Freiburg, Germany. (930-K10) Investigation of Laser Ablation of Silicon Nitride Passivation with Self-Doping Paste for Solar Cell Contacts. Adam Payne1, Kalyan Rapolu1, Preston Davis1, Vinodh Chandrasekaran1, Daniel Meier1, Baomin Xu2, Jim Zesch2, Karl Littau2. 1Suniva Inc, Norcross, GA, USA, 2Palo Alto Research Center, Palo Alto, CA, USA. (931-K14) 19.8 % Efficient PERC Silicon Solar Cells on Large Scale by using Inline Sputtering for Metallization. Dirk Reinwand1, Jan Specht1, David Stuewe1, Sonja Seitz1, Daniel Biro1, Ralf Preu1, Roland Trassl2. 1Fraunhofer Institute for Solar Energy Systems, Freiburg, Germany, 2Applied Materials GmbH & Co. KG, Alzenau, Germany. (932-K18) Towards Industrially Feasible High-Efficiency n-Type Si Solar Cells with Boron-Diffused Front Side Emitter – Combining Firing Stable Al2O3 Passivation and Fine-Line Printing. Armin Richter, Matthias Hörteis, Jan Benick, Stephan Henneck, Martin Hermle, Stefan W. Glunz. Fraunhofer Institute for Solar Energy Systems (ISE), Freiburg, Germany. (933-K22) PSG Trapping of Metal Contaminants During Belt Furnace Inline Phosphorus Diffusion in Crystalline Si Wafers. Paul J. Richter, Frank J. Bottari, David C. Wong. BTU International, Inc., Billerica, MA, USA. (934-K26) 30 µm Wide Contacts on Silicon Cells by Laser Transfer. Tobias C. Röder, Erik Hoffmann, Jürgen R. Köhler, Jürgen H. Werner. Institut für Physikalische Elektronik, Universtität Stuttgart, Stuttgart, Germany.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS

200


(935-K30) Screen Printable Ag-Al Metal Pastes for p+ Si Application in Solar Cells. Shahram Seyedmohammadi, Ed Graddy, Aziz Shaikh. Ferro Corp., Vista, CA, USA. (936-K34) Fabrication of Screen-Printed Multi-Crystalline Silicon Solar Cells Exceeding 16% Efficiency using Double Layer Anti-Reflective Coatings. Ji-myung Shim1, Il-hwan Kim1, Jun-young Choi1, Dong-joon Oh1, Kyeong-yeon Cho1, Eun-joo Lee1, Hyun-woo Lee1, Ji-sun Kim1, Soo-hong Lee2, Hae-seok Lee1. 1Shinsung Holdings, Seongnam, South Korea, 2Sejong University, Seoul, South Korea. (937-L4) Improvement in Al-alloyed Emitter of Rear-Junction n-type mc-Si Cells using a Stack of Pure Al and Screen-Printed Al Paste. Sukhvinder Singh1, Niels E. Posthuma1, Frederic Dross1, Jef Poortmans1, Robert Mertens1,2. 1IMEC, Leuven, Belgium, 2K.U. Leuevn, Leuven, Belgium. (938-L8) Performance of Transparent Conducting Oxide/Si Junction for the Emitter Wrap-Through Solar Cells. Jin-Seob Song1, Jung-Yup Yang1, Jun-Seok Lee2, Jae-Hwan Ha3, Jin-Pyo Hong2. 1Power & Industrial Systems R&D Center, Hyosung Corporation, 183, Hoge-Dong, Dongan-Ku, Anyang-Si, Gyeonggi-Do, South Korea, 2New Functional Materials and Devices Lab. Department of Physics, Hanyang University, Seoul, South Korea, 3Research Laboratory for Nano Devices Processing Lab, Division of Advanced Materials Science Engineering, Seoul, South Korea. (939-L12) Using Silicon Injection Phenomenon during Fire-Through Contact Formation to Improve Process-Control and Performance of Screen-Printed Multicrystalline-Silicon Solar Cells. Bhushan Sopori, Vishal Mehta. National Renewable Energy Laboratory, Golden, CO, USA. (940-L16) The Effect of TCO/a-Si:H Layer Interface on Silicon Hetero-Junction Solar Cells. Sung Ju Tark1, Seung Hun Lee1, Min Gu Kang1, Sungeun Park1, Young Do Kim1, Chang-Sik Son2, Jeong Chul Lee3, Donghwan Kim1. 1Korea University, Seoul, South Korea, 2Silla University, Busan, South Korea, 3Korea Institute of Energy Research, Daejeon, South Korea. (941-L20) All Screen-Printed 17.8% Homogeneous Emitter Solar Cells Using High Volume Manufacturing Equipment. Mason L Terry, Andreas Meisel, Sunil Shah, Tu Du. Innovalight, Sunnyvale, CA, USA. (942-L24) Large-scale and Enhanced Efficiency c-Si Solar Cell with Moth-Eye-like by using Self-Assembled Lithography. M. A. Tsai, H. C. Chen, H. W. Wang, Y. L. Tsai, P. C. Tseng, C. Y. Jang, Peichen Yu, H. C. Kuo. National Chiao Tung University, Hsinshu, Taiwan. (943-L28) Direct Write Metallization for Photovoltaic Cells and Scaling Thereof. Maikel F.A.M van Hest, Susan E. Habas, Jason M. Underwood, Robert M. Pasquarelli, Alex Miedaner, Calvin J. Curtis, David S. Ginley. National Renewable Energy Laboratory, Golden, CO, USA. (944-L32) Efficient Dicing of Silicon Ingots for Photovoltaic Applications. Cyrus P Vesvikar, Suhas S Joshi, Dongre G Ganesh, Ramesh K Singh. IIT Bombay, Mumbai, India.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS


201


(945-M2) Production Ready Novel Texture Etching Process for Fabrication of Single Crystalline Silicon Solar Cells. Kapila P. Wijekoon, Timothy Weidman, Steve Paak, Kenneth MacWilliams. Applied Materials, Santa Clara, CA, USA. (946-M6) Effect of Handling Stress on Resonance Ultrasonic Vibrations in Thin Silicon Wafers. Hao Wu1, Shreyes. N. Melkote1, Anton Belyaev2, Deven Cruson2, Igor Tarasov2, Sergei Ostapenko2. 1The George W. Woodruff School of Mechanical Engineering, Georgia Institute of Technology, Atlanta, GA, USA, 2Ultrasonic Technologies Inc., Tampa, FL, USA. (947-M9) Characterization of Dielectric Layer, Laser Damage and Edge Recombination in Miniature Silicon Solar Cells. Ngwe Soe Zin, Andrew Blakers. Australian National University, Canberra, Australia.


Area 5: Posters, Amorphous, nc, & Film Silicon: Fundamental Material Properties and Processing

Issues Chair(s): Tobias Sontheimer, Dries van Gestel (948-M15) Metal Induced Crystallization of Amorphous Silicon Using Layer-by-layer Technique with Gold Ultra Thin Layer. Masami Aono, Hiroaki Takiguchi, Takayuki Endo, Yoichi Okamoto, Hisashi Miyazaki, Jun Morimoto, Nobuaki Kitazawa, Yoshihisa Watanabe. National Defense Academy, 1-10-20 Hashirimizu, Yokosuka, Japan. (949-M17) Textured AZO on Silicon Oxy-nitride Barrier Films for Enhanced Light Trapping in Micromorph Tandem Junction Solar Cells. Yashraj Bhatnagar1, Brendan Mccomb1, Jianshe Tang1, Mani Subramani1, Wei D Wang1, Hong Zhang1, Stanley Wang2, Terence Hsu2, Daniel Severin3, Klaus Schuegraf1, Hari Ponnekanti1. 1Applied Materials Inc, Santa Clara, CA, USA, 2Applied Materials Taiwan, Taoyuan, Taiwan, 3Applied Materials Europe, Alzenau, Germany. (950-M19) Dynamics and Bonding of Bond-Centered Hydrogen in Amorphous Hydrogenated Si: Vibrational and Optical Signatures. Anatoli I. Shkrebtii1, Ihor. M Kupchak1,2, Timothy Teatro1, Zahraa A. Ibrahim1,3, Franco Gaspari1, Dmytro V. Korbutiak2. 1Faculty of Science, University of Ontario Institute of Technology, Oshawa, ON, Canada, 2V. Lashkarev Institute of Semiconductor Physics NAS, Kiev, Ukrenia, 3Department of Physics, University of Toronto, Toronto, ON, Canada. (951-M21) Aluminum Doped Hydrogenated Nanocrystalline Cubic Silicon Carbide Films Deposited by VHF-PECVD for p-type Window Layer of Silicon Based Thin-Film Solar Cells. Daisuke Hamashita1, Shinsuke Miyajima1, Akira Yamada1,2, Makoto Konagai1,2. 1Department of Physical Electronics, Tokyo Institute of Technology, Tokyo, Japan, 2Photovoltaics Research Center (PVREC), Tokyo Institute of Technology, Tokyo, Japan.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS

202


(952-M23) Low-Temperature Metal-Induced Crystallization of Mn-Containing Amorphous Ge Thin Films. Fabio A. Ferri, Antonio R. Zanatta. Instituto de Física de São Carlos - USP, São Carlos, Brazil. (953-M29) Correlation of a-Si:H Properties with Hydrogen Distribution. Franco Gaspari1, Anatoli Shkrebtii1, Ihor Kupchak1,2, Tim Teatro1, Zahra Ibrahim1,3. 1University of Ontario Institute of Technology, Oshawa, ON, Canada, 2V. Lashkarev Institute of Semiconductor Physics NAS, Kiev, Ukrenia, 3University of Toronto, Toronto, ON, Canada. (954-M31) High-density Plasma PECVD with High Gas Utilization. George X. Guo, Qing Zhu, Kai-an Wang. Ascentool Inc, Mountain View, CA, USA. (955-M33) Amorphous SiCN Thin Films. Volodymyr I Ivashchenko1, Oleksandr K Porada1, Liudmyla A Ivashchenko1, Petro M Lytvyn2, Igor M Hatsevych2, Borys M Romanuk2, Larysa A Grishnova1. 1Institute of Problems of Materials Science, NAS of Ukrenia, Kyiv, Ukrenia, 2Institute of Semiconductor Physics, NAS of Ukreniae, Kyiv, Ukrenia. (956-N1) Oxygen Elimination Effect in Silicon Thin Film by Neutral Beam Assisted CVD System at Room Temperature. Jin Nyoung Jang1, Byoung Chul Song1, Dong Hyeok Lee1, Daechul Kim2, Suk Jae Yoo2, Bonju Lee2, MunPyo Hong1. 1Korea University, Chungnam, Korea, 2National Fusion Research Institute, Deajeon, Korea. (957-N3) Development, Characterization and Interface Engineering of Films for Enhanced a:Si-H Solar Cell Performance. Pratik Joshi1, Steven Steen1, Kousik Sivakumar1, Wonkyun Yang2, Stephen Rossnagel1, Surbhi Mittal1, Mathias Steiner1, Deborah Neumayer1, Young-Hee Kim1. 1IBM T.J. Watson Research Labs, Yorktown Heights, NY, USA, 2Kunsun National University, Kunsun, South Korea. (958-N5) Synthesis of Si Nanoparticles from Freestanding Porous Silicon (Ps) Film Using Ultrasonication. Paresh Kale, Chetan Solanki. Indian Institute of Technology, Mumbai, India. (959-N7) A Novel Low Thermal Budget Thin-Film Polysilicon Fabrication Process for Large-Area, High-Throughput Solar Cell Production. Yue Kuo, Chen-Han Lin, Minghao Zhu. Texas A& M University, College Station, TX, USA. (960-N9) Effects of Hydrogen and Argon Plasma Treatment on Electrical and Optical Properties on Aluminum Doped Zinc Oxide Films Deposited by RF Magnetron Sputtering. Jaehyung Lee1, Hyunmin Ryu1, Gayeon Lee1, Donggun Lim2, Keajoon Yang2, Wonseok Choi3. 1Kunsan National University, Kunsan, Korea, 2Chungju National University, Chungju, Korea, 3Hanbat National University, Daejeon, Korea. (961-N11) Influence of Surface Texturing of AZO Films Deposited by RF Magnetron Sputtering on the Performance of Amorphous Silicon Thin Film Solar Cells. Jaehyung Lee1, Hyunmin Ryu1, Junsin Yi2. 1Kunsan National University, Kunsan, Korea, 2Sungkyunkwan University, Suwon, Korea.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS


203


(962-N13) Prepared Poly-Si Thin Film Crystallized by Al Induced with H-Plasma Passivation Treatment Simultaneously. Chong Luo1, Zhiguo Meng1, Juan Li1, Chunya Wu1, Hoi Sing Kwok2, Shaozhen Xiong Shaozhen Xiong1. 1Nankai University, Tianjin, China, 2HKUST, Hong Kong, China. (963-N15) Relative Crystallite Sizes for Thermally Annealed HWCVD a-Si:H Films with and without a Sub-Threshold Laser Fluence. M.S. Dabney, P.A. Parilla, B. To, H. Moutinho, A.H. Mahan, D.S. Ginley. NREL, Golden, CO, USA. (964-N17) ZnO:Al Films Deposited on Large Area (1.1 x 1.3 m2) Glass Substrates by an In-Line MF Magnetron Sputtering System. L. Zhang, Y. Feng, B. Lai, D. Ye, H. Wang, H. Jia, Y. Mai. Baoding Tianwei SolarFilms Co., Ltd, Baoding, China. (965-N19) mc-Si Thin Films by Hydrogen Plasma Assisted Vacuum Evaporation Deposition. Diego O Miranda1, Thiago D. O Moura1, Romeu J Santana1, Gilson R Guimarães1, Erich R S karger1, Antônia Sônia A.C Diniz2, José Roberto T Branco1. 1Fundação Centro Tecnológico de Minas Gerais, Belo Horizonte, Brazil, 2Companhia Energética de Minas Gerais, Belo Horizonte, Brazil. (966-N21) Enhancement of Crystallinity in ZnO:Al Films Using a Two-Step Process Involving the Control of the Oxygen Pressure. Taeho Moon, Wonki Yoon, Kwang Sun Ji, Seh-Won Ahn, Minho Joo, Hui Youn Shin, Kyuho Park, Heon-Min Lee. LG Electronics, Seoul, South Korea. (967-N23) Polycrystalline Silicon Films and Solar Cells by FBR-CVD. Angel Sanjurjo, Kai Lau, Jordi Perez, Lorenza Moro. SRI International, Menlo Park, CA, USA. (968-N29) Effects of Hydrogen Dilution on Electron Density in Multi-Hollow Discharges with Magnetic Field for a-Si:H Film Deposition. Kazunori Koga, Yuuki Kawashima, Kenta Nakahara, Takeaki Matsunaga, William M Nakamura, Masaharu Shiratani. Kyushu University, Fukuoka, Japan. (969-N31) Deposition of Cluster-Free P-doped a-Si:H Films using a Multi-Hollow Discharge Plasma CVD Method. Kenta Nakahara, Yuuki Kawashima, Takeaki Matsunaga, William M Nakamura, Kazunori Koga, Masaharu Shiratani. Kyushu University, Fukuoka, Japan. (970-N33) Carrier Transport Properties of Flash-Lamp-Crystallized Poly-Si Films. Keisuke Ohdaira1,2, Takuya Nishikawa1, Shohei Ishii1, Naohito Tomura1, Hideki Matsumura1. 1Japan Advanced Institute of Science and Technology, Ishikawa, Japan, 2PRESTO, Japan Science and Technology Agency, Saitama, Japan. (971-O1) Mechanism of Preferential Orientation in Microcrystalline Silicon Growth and Its Influence on Post-Oxidation Property. Kimihiko Saito1,2, Michio Kondo1,2. 1National Institute of Advanced Industrial Science and Technology, Tsukuba, Ibaraki, Japan, 2Tokyo Institute of Technology, Yokohama, Kanagawa, Japan. (972-O3) Anomalous Conductivity Behavior of Microcrystalline Silicon. Ruurd W. Lof, Ruud E.I. Schropp. Utrecht University, Debye Institute, Nanophotonics - Physics of Devices, Utrecht, Netherlands.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS

204


(973-O5) Continuous In-Line Hot-Wire Chemical Vapor Deposition of Thin Film Silicon p-i-n Solar Cells. Ruud E.I. Schropp, Caspar O. van Bommel, Karine H.M. van der Werf, Yanchao Liu, Xin Jin. Utrecht University, Debye Institute, Nanophotonics - Physics of Devices, Utrecht, Netherlands. (974-O7) Carrier Lifetime Measurements of Nanocrystalline Silicon Thin Films using Transmission Modulated Photoconductive Decay. Brian J Simonds1,2, Baojie Yan4, Richard K Ahrenkiel2,3, P. Craig Taylor1,2. 1Department of Physics, Colorado School of Mines, Golden, CO, USA, 2Renewable Energy Materials Research Science and Engineering Center, Colorado School of Mines, Golden, CO, USA, 3Department of Merallurgical and Materials Engineering, Colorado School of Mines, Golden, CO, USA, 4United Solar Ovonic, LLC, Troy, MI, USA. (975-O9) Control of Crystalline Volume Fraction of μc-Si Thin Film Using 40.68 MHz PECVD System for Solar Cell Application. Fu-Ching Tung, Man-Chi Huang, Tsung-Shou Chin, Nguyen Chi Lang, Pei-Shan Wu, Edward Yi Chang, Jin-Hua Huang. ITRI/MSL, Hsinchu, Taiwan. (976-O11) Optical Investigation of a-Si:H Films with Si Nanocrystals. G. Polupan1, A. Vivas Hernández1, T. Torchynska2, L. Shcherbyna3. 1ESIME - National Polytechnic Institute, México D.F., Mexico, 2ESFM - National Polytechnic Institute, México D.F., Mexico, 3V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences, Kyiv, Ukrenia. (977-O13) Raman Study of Stress Effect in Silicon Rich Carbide (SiCX) Film by Furnace and Rapid Thermal Annealing for Photovoltaic Applications. Zhenyu Wan, Shujuan Huang, Martin Green, Gavin Conibeer. University of New South Wales, Sydney, Australia. (978-O15) On the Bandgap of Hydrogenated Nanocrystalline Silicon Thin Films. Baojie Yan1, Guozhen Yue1, Laura Sivec1, Chun-Sheng Jiang2, Yanfa Yan2, Jeffrey Yang1, Subhendu Guha1. 1United Solar Ovonic LLC, Troy, MI, USA, 2National Renewable Energy Laboratory, Golden, CO, USA. (979-O17) Property Drift and Control for Intrinsic Microcrystalline Silicon Thin Film Continuous Deposition in a Single Chamber System. Xiaodan Zhang, Guanghong Wang, Xinxia Zheng, Changchun Wei, Jian Sun, Shaozhen Xiong, Xinhua Geng, Ying Zhao. Institute of Photo-electronic Thin Film Devices and Technology of Nankai University, Tianjin, China.

TH

UR

SD

AY

PO

STER

PR

ES

EN

TA

TIO

NS


205


AUTHOR INDEX

Abbott, M - 332, 928Abduljabar, A - 126Abdullin, K - 534Abe, T - 186Aberle, A - 681Abou-Ras, D - 110Abrari, M - 0Adachi, M - 855Adams, J - 1Adams, M - 814Adams, R - 384Adhikary, S - 424Adiga, N - 340, 351Adiyabat, A - 558, 665Adkins, D - 191, 391Adurodija, O - 600Aernouts, T - 252Agarwal, A - 361, 633Agarwal, S - 433Agarwal, V - 230, 652, 715Ager III, J - 246Agert, C - 350Agrawal, M - 555, 80Agrawal, R - 887Agui, T - 109Aguilar-Hernández, J - 471Ahlswede, E - 898Ahn, B - 895Ahn, S - 449, 455, 675, 966Ahrenkiel, P - 507Ahrenkiel, R - 195, 314, 974Ahsan, N - 504Aiken, D - 31, 33Aimez, V - 289, 762Aiona, Jr., J - 5Aitasalo, T - 683, 684Akahane, K - 432, 445Akaki, Y - 595Akatsuka, M - 135Akhil, A - 132Akimoto, K - 208Akisawa, A - 761Akpa, O - 450Aksu, S - 183, 51Al Taher, O - 479, 55Alam, M - 27Alami Fettouhi, A - 559Al-amin, C - 736Alberi, K - 145, 334Albert, M - 545Albin, D - 0, 270, 271, 412, 466, 88Alboiez, A - 126Albright, S - 2, 908Aleman, M - 296Alemu, A - 284, 637, 645, 734, 97Alén, B - 221Alers, G - 408Alexander, J - 370Algora, C - 161Aliberti, P - 21Al-Jassim, M - 406, 466, 528, 553, 63, 742Al-Jassim, m - 625Alkaisi, M - 842Allan, D - 643Allardyce, G - 243, 910Allebé, C - 798

Allebe, C - 809Alley, N - 373, 854Alm, B - 0Aloni, S - 423Alonso Abella, M - 725Alonso-Álvarez, D - 221Al-Saaedi, Y - 126Alsharif, S - 641Altermatt, P - 531, 93Altosaar, M - 474, 605Alvarez, M - 229Amadon, J - 54Amano, T - 442Ameen, S - 862Amin, N - 368, 469, 516, 878An, J - 897Anctil, A - 170, 370Anderberg, A - 599Anders, R - 903Andersen, J - 282Anderson, I - 470Anderson, J - 368Anderson, j - 516Anderson, Jr., M - 654Anderson, K - 256, 584Anderson, P - 450Anderson, R - 278Anderson, T - 238, 905Andrews, G - 701Andrews, J - 257Antolín, E - 221Antoniadis, H - 276, 334Aono, M - 948Appel, J - 297, 311, 820Aquino, A - 879Arafune, K - 392Araki, K - 761Aramoto, T - 50Ardalan, P - 227Arehart, A - 480Arenas, O - 762Arends, T - 67Arès, R - 289, 762Arhenkiel, R - 794Arkun, E - 860, 861Armstrong, N - 127Arredondo, C - 576, 601Aryal, P - 397Asai, Y - 708Asaumi, T - 793Asher, S - 150Assalone, D - 395Asselbergs, M - 481Attygale, D - 146Attygalle, D - 396, 397Atwater, H - 175, 219, 245, 339Augusto, A - 517Avery, J - 768Aya, Y - 268Aydil, E - 452, 617Aygun, S - 801B.R., U - 633Babaei, H - 0, 0Babbitt, C - 170Badahdah, A - 126Bae, B - 269, 356Bae, E - 620, 880Baek, S - 337, 422Baer, M - 15

206


Baert, K - 809Bagdahn, J - 294, 417Baggio, N - 685Bagnall, D - 358Baik, S - 341Baik, Y - 603Bailey, C - 282, 427, 495, 94Bailey, S - 202, 630Baker-Finch, S - 530, 531Bakhru, H - 810Bakke, J - 227Balakrishnan, G - 516Balandin, A - 635Baldrias, M - 674Ballard, I - 287Ballif, C - 174, 360Ban, K - 425, 856Bandyopadhyaya, R - 440Banerjee, A - 267, 664Banerjee, R - 580Banguero, E - 585Bansal, S - 270, 271, 461Bao, J - 533Bao, T - 301, 911Bao, X - 423Bär, M - 149Bardfield, R - 631, 640Bärenklau, M - 253Barnes, T - 383Barnett, A - 323, 503, 535, 536, 689, 757, 796, 866Barnham, K - 1, 120, 683Baroughi, M - 746, 825, 829Barr, B - 243Barr, R - 518, 910Barrett, K - 693Barrigón, E - 161Barth, K - 464Bartsch, J - 298Bassiouny, O - 101Basso, T - 136, 584Bateman, N - 329Battaglia, C - 174Baudrit, M - 443Bauhuis, G - 287Baur, C - 160, 260Bausch, G - 307Bay, N - 153Bayat, K - 733, 746Beall, C - 145Beard, M - 874, 95Bearda, T - 549, 925Beaucarne, G - 307, 702Bechmann, P - 459Bechnik, B - 594Becker, C - 143Becker, J - 929Bedi, B - 577Beeman, J - 754Beernink, K - 267, 664Beese, S - 278Beglau, D - 267, 664Behrens, T - 167Beketov, B - 534Belledin, U - 17Bellet, D - 443BELLET, D - 836Beltramini, M - 192Belyaev, A - 946Bendapudi, S - 465Bende, E - 19Benedikt, B - 35

Benick, J - 154, 214, 932Bennett, C - 405Bennett, I - 416, 541, 706Bensaoula, A - 632, 858Bensch, W - 56Bent, S - 227, 451, 477BERCU, B - 775Bergeson, J - 383, 747Berghold, J - 709Bermudez, V - 161, 199, 415Bernal, E - 692Bernardis, S - 89Berry, J - 248, 250, 30, 841Bertness, K - 37, 393Bertoni, M - 112, 234, 871, 89, 92Best, S - 560Bett, A - 160, 285, 56Betts, T - 567, 666Bhandaru, S - 467, 472, 476Bhatia, C - 362, 870Bhatnagar, Y - 80, 949Bhattacharya, R - 748Bhattacharya, S - 819Bhogra, R - 577, 819Bhusari, D - 35, 55Biegala, T - 459Biesecker, M - 733Bilger, G - 313Billets, S - 166, 32Bills, B - 825, 829, 830, 834Birkmire, R - 178, 297, 311, 820Birmann, K - 243Biro, D - 17, 240, 319, 791, 800, 920, 931Bissels, G - 481Biswas, R - 338Bitnar, B - 240Bitsuamlak, G - 182Bittner, Z - 495Bivour, M - 299, 929Black, C - 843Blackburn, J - 383Blakers, A - 193, 723, 783, 784, 947Błażejewska, K - 594Bliss, M - 567, 666Bloesch, P - 151Blosse, A - 406Blum, M - 149Blumenfeld, P - 59Boca, A - 35, 55, 857Bochmann, A - 159Boden, S - 358Boieriu, P - 459Boisvert, J - 35, 857Bonafede, S - 122Boney, C - 632, 858Bonner, C - 190Bonnet-Eymard, M - 88Boo, S - 538, 539Book, F - 300Boone, T - 51Boonmee, C - 364Bor, H - 597Bordin, N - 525Borland, W - 801, 804Boronat, A - 280Bosco, N - 66Bose, R - 120


207


Bosiljevac, T - 591Bosio, A - 181Bottari, F - 301, 911, 933Boumsellek, S - 893Bourne, B - 255, 568Bouwmeester, J - 265Bowden, S - 316, 318, 670Bower, W - 132Boyle, J - 85, 889Bradford, R - 700Bragagnolo, J - 519Branca, A - 48Branco, J - 965Brandhorst, H - 560Brandt, R - 55Branz, H - 145, 553, 62Bratin, P - 615Brauers, M - 723Braun, S - 300Braun, W - 243Braunecker, W - 371Breen, M - 164Brémaud, D - 151Bremner, S - 856Brendel, R - 115, 213, 279, 330, 790, 93Brennan, T - 227Brenner, M - 480, 661Bresciani, P - 555Brett, M - 429, 849Brindley, H - 765Briones, F - 221Britt, J - 2, 908Broesler, R - 859Brongersma, M - 222Bronsveld, P - 185Brown, D - 179, 54Brown, J - 189Brown, M - 701Brucker, E - 486Brueck, S - 516Brunner, S - 13Bruton, T - 763Büchtemann, A - 120Budai, J - 405Budhraja, V - 544Budiman, M - 283Buecheler, S - 151, 236, 881Bui, K - 631, 640Bukovnik, R - 122Bultman, G - 402Bundgaard, E - 251Bunea, M - 190Buonassisi, T - 112, 295, 745, 871, 89, 92Burns, G - 307Burroughs, S - 122Burrows, M - 332Burst, J - 596Burton-Pye, B - 843Busquet, S - 667Buyuklimanli, T - 904Bye, J - 913Byrnes, D - 483Caballero, R - 13Cahen, D - 731, 84Cai, S - 729Call, N - 407, 544Calnan, S - 336Calvo-Barrio, L - 888Camacho-Cuardrado, J - 307

Camel, D - 326Cameron, C - 133, 255, 258Campbell, R - 764Campbell, S - 452, 617Cao, Q - 148Cao, X - 340, 351Caraman, I - 476Carapella, J - 507, 510Carcia, P - 274Carlin, A - 489, 661Carlson, D - 277Carmody, M - 459Carroll, D - 384Carter, S - 470Castañer, L - 280Castellanos, S - 295, 92Ceder, G - 739Cesar, I - 19Chakrabarti, S - 424Champness, C - 210Chan, B - 809Chan, M - 739Chan, N - 765Chan, P - 729Chan, R - 910Chandrasekaran, R - 179Chandrasekaran, V - 930Chang, C - 121, 302, 394, 786, 848Chang, E - 975Chang, F - 121Chang, H - 787Chang, J - 882Chang, S - 0, 917, 918Chang, T - 302Chang, W - 0, 786, 919Chang, Y - 410, 604, 885Changmoang, P - 437Chao, C - 102Chao, J - 225Chaouachi, A - 726Chapman, P - 101Chatten, A - 120Chaturvedi, P - 681Chaudhari, V - 303, 909Chaudhuri, B - 765Chawla, V - 451Chelvanathan, P - 878Chen, B - 912Chen, C - 0, 340, 351, 352, 365, 366, 485, 597, 616, 690Chen, D - 278, 453Chen, F - 223, 254, 365, 546, 845Chen, H - 514, 515, 942Chen, J - 211, 396, 544, 799Chen, K - 579, 845Chen, L - 742, 842Chen, M - 642, 662Chen, S - 875, 912Chen, W - 305, 365Chen, X - 0, 308, 928Chen, Y - 485, 597, 616, 714, 799, 914, 918Chen, Z - 505Cheng, A - 452Cheng, L - 804Cheng, T - 799Cheng, Z - 453Chenlo, F - 725Chetrus, P - 475

208


Chey, S - 148Chhabra, B - 304, 573Chi, D - 870Chi, E - 539Chi, W - 497, 642Chiba, Y - 50Chicana-Nuncebay, W - 471Chien, S - 254Chin, J - 479Chin, K - 212, 453, 454Chin, T - 975Ching-Fuh, L - 380Chiou, Y - 366Chirila, A - 151, 881, 888Chirita, A - 476Chiu, M - 121Chiu, P - 290Cho, A - 449, 455Cho, B - 31, 32, 33, 639, 657Cho, D - 883Cho, E - 807Cho, H - 598, 788, 899Cho, J - 337, 620, 679, 813cho, J - 880Cho, K - 306, 328, 936Cho, M - 263, 651Cho, S - 839Cho, Y - 352, 869Choi, C - 540Choi, D - 679Choi, I - 675Choi, J - 306, 328, 566, 808, 936Choi, S - 208, 874, 900, 96Choi, W - 458, 808, 960Chong, K - 766, 767Chou, M - 485Chouder, A - 571Chow, S - 762Chowdhury, S - 424Christensen, S - 248Christiana, H - 741Christiansen, S - 159, 418Chu, C - 848Chu, Y - 343Chuang, C - 882, 919Chubb, D - 663Chumney, D - 33Chung, B - 278Chung, Y - 883Church, K - 308Cieslak, K - 590, 924Cimiotti, G - 153Ciocan, E - 395Ciocan, R - 395Ciscato, D - 524Clapper, P - 631Clark, A - 860, 861Clark, E - 663Clark, O - 358Clark, R - 277Clemens, B - 451Clement, F - 319, 800Clews, P - 288, 309Cocco, F - 326Coddington, M - 136, 256, 584Cohen, J - 85Cohen, P - 755Cohen, U - 520Cokin, D - 164

Coletti, G - 185, 401, 89Collin, L - 762Collins, E - 587Collins, R - 146, 211, 396, 397, 433, 49Collison, C - 370Compaan, A - 14, 15, 239, 457Conibeer, G - 21, 438, 448, 977Conroy, C - 179, 54CONSONNI, V - 836Contreras, M - 900Contreras-Puente, G - 469, 471Cook, C - 0, 106, 884Cook, J - 289Cooper, I - 155, 307, 312Cormode, D - 292, 572Cornagliotti, E - 549, 89Cornfeld, A - 31, 32, 33Cotal, H - 60Cotsell, J - 70Cousins, P - 190, 71Coutts, T - 142, 596Cowan, S - 26Cravens, R - 479Creatore, M - 147, 359, 48Creazzo, T - 535, 796Cress, C - 413Cronin, A - 292, 572Cruson, D - 946Cruz, S - 505Cruz-Campa, J - 288, 309, 773Cui, Y - 117, 131, 177, 222, 490Culver, B - 274Cunningham, D - 277Curran, S - 228, 373, 851, 854Curtin, M - 535, 796Curtis, C - 611, 890, 943Dabney, M - 963Dagva, B - 558Dahal, L - 146, 396, 397Dahal, S - 425, 856Dai, N - 0Dai, X - 815Daineka, D - 310Dalaker, H - 521, 522, 523Dalal, V - 338Dameron, A - 248, 68Damon-Lacoste, J - 310Danel, A - 18Daniel, J - 783Danilson, M - 474, 605Danner, A - 362, 870Darveau, S - 752, 884Das, A - 155, 217Das, K - 450Das, U - 297, 311, 820Dastgheib-Shirazi, A - 300Datta, D - 128Dauksher, B - 670David, C - 336Davies, E - 723Davis, C - 592Davis, J - 639Davis, K - 737Davis, P - 930Davoudi, A - 101


209


de Jong, P - 706, 721de Monsabert, T - 148De Santi, G - 0De Valle, S - 229de Villers, B - 224DeAngelis, A - 410, 885Deangelis, A - 604DeBlasio, R - 38Debora, P - 565Deceglie, M - 339Decker, R - 163Deep, M - 72DeGroot, M - 273DeHart, C - 272, 901, 907Dekkers, H - 89del Canizo, C - 112del Cueto, J - 270, 599Delahoy, A - 358Deline, C - 100, 599Deline, V - 148DeMaggio, G - 267, 664Demant, M - 116Dempsey, C - 59Demtsu, S - 270, 271Deng, H - 0Deng, J - 46Deng, X - 340, 351Deng, Y - 52Denis, C - 18Denlinger, J - 149Dennis, T - 71Derkacs, D - 290Deshpande, A - 544Despeisse, M - 360Deuel, D - 716Deutsch, T - 486Devayajanam, S - 545Dewald, J - 228Deymier, P - 229Dhakal, R - 482Dhere, N - 613, 728Dhere, R - 237, 459, 466, 625, 87, 88Dhople, S - 101Dias, S - 373, 854Diaz, J - 33Dickey, E - 49Dikhanbayev, K - 743Dimitrov, D - 822Dimock, F - 301Dimroth, F - 285, 34, 56Ding, C - 891Ding, D - 502, 732Ding, i - 117Ding, I - 131Ding, J - 578Ding, P - 278Dingemans, G - 789, 814Diniz, A - 965Dinkel, C - 53, 907DiSanti, G - 0Doble, D - 232, 600, 698DOISNEAU, B - 836Dominé, D - 174Dong, A - 556Dong, H - 518Dong, J - 758Dongyun, W - 0Doni, A - 586Donovan, M - 568Doolla, S - 580Dorn, D - 668

Dornich, K - 197, 419Dovidenko, K - 461Dovrat, M - 312Downard, E - 32Drain, C - 843Drevet, B - 326Drori, A - 525Dross, F - 529, 937Du, C - 305, 822, 912Du, J - 554Du, T - 941Du, W - 340, 351Dubarry, M - 667Dubey, M - 827, 828Dubois, L - 923Dubois, S - 326Dubon, O - 754Ducros, C - 357Duda, A - 145, 487, 510, 552Duda, M - 0, 104Duell, M - 232, 600, 698Duenow, J - 237, 87, 88Duggan, G - 287Duggan, M - 200Dughiero, F - 524, 586Dullweber, T - 330Dunlop, E - 683Dunsky, C - 53, 907Durlinger, B - 581Duttagupta, S - 230Duty, C - 405Dwyer, S - 591Dybiec, M - 403Eberspacher, C - 80Ebert, C - 483Ebert, M - 417Ebong, A - 307, 312, 812Ebser, J - 90Edmonds, J - 8Edmondson, K - 35Egan, R - 143, 144Ehlert, S - 267, 664Ehling, C - 313Einhaus, R - 326Eisenberg, N - 525Ekins-Daukes, N - 1, 765Elazari, A - 390, 575Eldada, L - 52, 890Elder, W - 1Elerath, J - 123Elfiky, D - 634Ellis, A - 74Ellsworth, J - 459Elowe, P - 273Emelyanov, V - 687Emery, K - 395Emziane, M - 484, 774Endo, T - 948Enebakk, E - 184Enebish, N - 558Engelhart, P - 789Enjalbert, N - 326Enzenroth, R - 464Ergashev, B - 469Ermer, J - 479, 55Ernst, M - 790Erslev, P - 85Ertekin, E - 745Esenturk, O - 375Eser, E - 152, 178Es’haghi Gorji, N - 0Eskenazi, M - 639

210


Espadas, C - 565Espinet, P - 161Even, R - 312Everett, V - 193, 723, 770, 783, 784Ewan, J - 667Exstrom, C - 752, 884Fabero, F - 725Fafard, S - 289Fahrner, W - 156, 382Fakra, S - 745Falber, A - 843Fallah, B - 218Fallahazad, B - 399Fallisch, A - 791Fan, Q - 340, 351Fan, S - 117, 177, 25, 490Fan, Y - 114Fang, H - 555Fang, J - 612Fang, L - 269, 341Fardi, H - 426Farnsworth, K - 67Farrokh Baroughi, M - 733, 830, 834Farrokh-Baroughi, M - 551Farva, U - 905Fatemi, N - 32Fathi, E - 342Fathi, J - 0Favier, A - 18Fecych, A - 92Fedorov, V - 475Fedoseyev, A - 635Feist, R - 617, 886Feldman, A - 314Felix, R - 149Fella, C - 881Feng, S - 485Feng, Y - 21, 964Fenning, D - 112, 89Ferekides, C - 465, 467, 469, 472, 476, 903Ferenczi, T - 692Ferguson, D - 636Ferguson, I - 118Ferri, F - 952Ferry, V - 175Fetzer, C - 55, 640Fiegna, C - 555Field, D - 582Fields, S - 152, 178Fife, J - 697Fine, K - 779Fish, B - 804Fisher, J - 169, 639Fisher, K - 409, 927Flatico, J - 264Fleischauer, M - 849Fleischmann, C - 153Flood, D - 863Flynn, G - 59Fobare, D - 179, 54Fogel, K - 148Fonash, S - 220Fong, P - 473Fontane, X - 415, 888Forbes, D - 282, 427, 495, 94Ford, G - 887Ford, J - 125Foresi, J - 59

Forzan, M - 524Fossum, J - 792Fournier, K - 639Foxon, C - 859Fraas, J - 768Fraas, L - 768Fraile Montoro, D - 111Frakie, R - 452France, R - 486, 510Frank, O - 709Frantziskonis, G - 229Frechette, L - 762Frei, M - 555, 80Freitag, J - 51Freitas, J - 413Freundlich, A - 247, 284, 637, 645, 669, 734, 97Frey, G - 847Frey, J - 293Friedman, D - 487Fromer, N - 0Frost, J - 60Fthenakis, V - 138Fu, J - 278Fu, M - 384Fuertes, D - 280Fujishima, D - 793Fujiwara, K - 188Fukuda, S - 266Fulgoni, D - 287Fuller, N - 927Funatani, T - 797Funderburk, V - 263Fuqiang, H - 0Furman, B - 122Furno, M - 129Furue, S - 208, 442Fuyuki, T - 315, 398, 548, 797Gabriel, J - 122Gaddy, E - 163, 644Gaillard, N - 410, 604, 885Galante, M - 606Galipeau, D - 374, 377, 482, 746, 825, 829, 834Gall, S - 143Galleano, R - 683, 684Ganapati, V - 295Ganesh, D - 944Gao, F - 804Gao, L - 729Gao, P - 729Gao, W - 395Gapud, A - 641Garboushian, V - 189Garcia, A - 372Garcia, I - 161Garnett, E - 222, 439Gasin, P - 475, 476Gasner, S - 32Gaspari, F - 404, 950, 953Gasulla, M - 734Gatz, S - 330, 93Gedvilas, L - 487Geerligs, L - 19Geiss, D - 0Geissendoerfer, S - 350Geisz, J - 487, 510Gelak, E - 673Gemmel, C - 898Geng, X - 369, 979


211


Gennett, T - 234, 248, 272, 606, 841Genoe, J - 252George, D - 116George, G - 684George, M - 794Georghiou, G - 259, 574Georgiou, G - 453Gerger, A - 535, 796Gerstmaier, T - 56Gessert, T - 237, 272, 454, 596, 621, 87, 88Gfroerer, T - 488Gherasoiu, I - 246Ghosal, K - 122Ghosh, K - 316, 318, 670Gibb, J - 166Giesecke, J - 196Gillanders, M - 640Ginley, D - 150, 234, 248, 250, 30, 371, 372, 606, 611, 747, 841, 890, 943, 963Ginzburg, L - 278Giolando, D - 14Girotto, C - 252Glaeser, G - 703Glassmaker, N - 701Glatkowski, P - 857Glatthaar, M - 187Glennie, J - 854Glick, S - 272, 69Glunz, S - 154, 20, 214, 244, 298, 299, 312, 921, 929, 932Glynn, S - 272, 621, 901, 907Gogolin, R - 115Golnas, T - 134Gombert, A - 56Gomez-Castro, F - 570, 699Gong, C - 198, 795, 925Gong, X - 875Gonzales, M - 264González, L - 221Gonzalez, M - 120, 413Gonzalez, S - 132, 693, 716González, Y - 221Good, E - 403Goodrich, A - 133Gordillo, G - 576, 585, 601Gordon, D - 769Gordon, I - 72, 925Gorji, N - 0Gorjia, N - 0Gorman, J - 406Gorrie, C - 619Goss, B - 567Goswami, Y - 469Gothait, H - 312Gottschalg, R - 567, 666Gottschlag, R - 291Gou, J - 641Govindarajan, S - 602Graddy, E - 916, 935Graf, P - 619Granata, J - 587, 618Granata, S - 310Grandum, S - 184Granek, F - 153, 244Granneman, E - 19Grant, N - 214Grases, C - 565

Grases, M - 565Grassman, T - 489Gray, A - 122Gray, J - 491, 492, 735, 785Green, M - 137, 21, 438, 448, 47, 977Greer, L - 264Gregory, D - 719Grewe, O - 156, 382Grimmer, C - 779Grishnova, L - 955Grobgeld, D - 525Groppelli, P - 781Grossberg, M - 474Grosset-Bourbange, D - 326Grossman, J - 745Grubbs, R - 309Gu, A - 490Guan, Y - 245Gudgel, T - 602Guettler, D - 151, 881, 888Guha, S - 126, 218, 267, 399, 664, 978Guhabiswas, D - 545Guichoux, M - 721Guillemoles, J - 21, 22Guimarães, G - 965Gulati, S - 182Gulkowski, S - 590, 924Gunawan, O - 148, 218, 399Gundel, P - 400Gundermann, M - 312Guntur, V - 472Guo, G - 954Guo, H - 555, 922Guo, J - 882Guo, Q - 887Guo, Y - 911Guo-Dong, H - 380Gupta, A - 329Gupta, V - 288, 309, 773Guter, W - 285, 34, 56Guzie, B - 657Gwak, J - 449, 455Ha, J - 938Haas, A - 491, 492, 735, 785Haas, W - 872Habas, S - 890, 943Habenicht, H - 401Habib, M - 736Hacke, P - 66Hahn, G - 16, 300, 89, 90Hakajima, A - 266Hakkulov, M - 469Hakuma, H - 50Haldar, A - 373, 851Halder, N - 424Haley, R - 617Hall, J - 646Hall, T - 289Hallam, B - 157, 328Hallberg, I - 204Haller, E - 859Halm, A - 242, 325Ham, C - 620, 880Hamashita, D - 951Hammond, S - 372Hampton, D - 488Han, C - 869Han, D - 395Han, J - 906Han, K - 864

212


Han, L - 865Han, M - 347, 499Han, W - 883Han, X - 493, 501, 770, 81, 864Hanket, G - 178, 85, 889Hanley, J - 631Hao, R - 535, 796Hara, K - 317, 444Hara, R - 135Harder, N - 115, 279, 93Harley, G - 71Harper, A - 591Harris, C - 290Harris, J - 490Harris, Jr., J - 439Harris, K - 429Harris, M - 495Harrison, S - 18Hartsoch, N - 3Harvey, J - 193, 784Hasegawa, M - 797Hasoon, F - 552Hatano, M - 446Hatayama, T - 548Hatsevych, I - 955Haug, F - 174Haug, V - 898Haunschild, J - 116, 187Haupt, O - 253Hausgen, P - 654Haverkamp, E - 287, 481Hayakawa, H - 262Hayase, S - 130Hayes, M - 519He, H - 827, 828He, L - 62, 771Heath, J - 63Hebert, P - 479, 55Heeger, A - 26, 73Hegedus, S - 274, 293, 297, 311, 820Heilweil, E - 375Heinemann, S - 926Heinz, F - 400Heinzel, D - 462Helgesen, G - 913Heng, B - 278Henini, M - 858Henke, B - 417Henley, F - 275Henneck, S - 932Henning, A - 800Heo, G - 389Heo, S - 788Heo, Y - 356Herasimenka, S - 316, 318, 670Heremans, P - 252Herfurth, H - 232, 600, 926Herig, C - 205Herman, J - 658Hermle, M - 214, 244, 299, 921, 929, 932Hernandez, I - 632, 858Hernández, J - 221, 576, 798Hernandez, J - 809Herrera, M - 221Herring, C - 354Herron, S - 477Hersh, P - 890

Heske, C - 149, 15het Mannetje, H - 235Hickel, P - 18Hickman, N - 737Higo, A - 58Hilfiker, J - 464Hill, G - 1Hillhouse, H - 887Hillier, G - 513Hinzer, K - 289, 762Hirata, K - 548, 797Hirose, K - 262Hisamatsu, T - 262Hishida, M - 268HISHIKAWA, Y - 671Hlaing Oo, W - 463Ho, C - 343Ho, W - 799, 918Ho, Y - 623Hoang, B - 263Hodges, D - 472, 476Hoe, G - 897Hoefelmeyer, J - 846Hoehne, H - 709Hoenig, R - 319, 800Hoex, B - 681Hofer, F - 872Hoffman, R - 452Hoffmann, E - 934Hofstetter, J - 112Hoheisel, R - 34Holt, A - 537, 816, 913Hom, D - 640Honda, T - 494Hong, B - 824Hong, J - 812, 938Hong, M - 956Hong, S - 597, 616Hongsingthong, A - 344, 367Honsberg, C - 118, 304, 316, 318, 425, 573, 670, 856Hook, D - 801Hoppe, H - 253Hornbostel, M - 533Horner, G - 402, 403Hörteis, M - 154, 298, 932Horteis, M - 312Hoskin, J - 631Hossain, M - 878Hou, G - 340, 351Hovel, H - 802Hovestad, A - 235Howard, A - 32, 654Hsiang, K - 914Hsieh, A - 21Hsieh, C - 353Hsieh, H - 710Hsieh, T - 738, 882Hsu, C - 117, 177, 345, 835Hsu, M - 786, 848, 914Hsu, P - 579Hsu, S - 882, 919Hsu, T - 949Hsu, W - 690, 822, 912Hsueh, C - 343Hu, H - 278, 370Hu, S - 0, 490Hu, W - 428Huang, B - 579Huang, C - 283, 343, 394, 891, 912


213


Huang, H - 768Huang, J - 226, 345, 47, 848, 975Huang, M - 223, 810, 975Huang, P - 799Huang, Q - 927Huang, S - 21, 503, 866, 977Huang, Z - 146, 396, 397, 429Hubbard, S - 282, 427, 495, 635, 94Hubbimov, A - 469Hudelson, S - 112, 89Hudson, J - 402, 403Huffaker, D - 224Huh, Y - 482Huis in ‘t Veld, B - 235Hummel, S - 697Hund, T - 693Hung, S - 912Huo, Y - 490Hupka, L - 409Hurst, K - 411Hwang, B - 702Hwang, F - 835Hwang, H - 566Hwang, M - 807Ianno, N - 638, 752, 884Ibrahim, A - 803Ibrahim, Z - 404, 950, 953Igarashi, M - 283Ikeda, K - 501IKKI, O - 43Illiberi, A - 147, 48Im, J - 269, 72Imaizumi, M - 109, 165, 262, 36, 641, 650, 651, 655, 656, 660Imtiaz, A - 393Inagaki, M - 493, 494, 496, 501Inaji, T - 447Inculet, I - 475Ingersoll, M - 884Ing-Jye, W - 380Ingler, W - 340, 351Iniyan, S - 783Inoue, H - 793Inoue, T - 428, 435, 86invited, - 0Invited, - 105Ionkin, A - 804Irikawa, J - 805Isaacs-Smith, T - 450Ishii, S - 970Ishizuka, S - 12, 208Ito, T - 135, 165Ivanov, N - 558Ivashchenko, L - 955Ivashchenko, V - 955Iwai, T - 660Iwaniczko, E - 145, 552, 62Iyer, S - 128, 29Izquierdo-Roca, V - 415, 888J, N - 468, 717Jackson, E - 261Jacobson, J - 871Jäger, U - 17, 320, 806Jaime-Ferrer, J - 415Jain, S - 430

Jamil, M - 118Jamora, A - 860Jampana, B - 118Jan, Y - 891Jang, C - 514, 515, 942Jang, J - 956Jansen, T - 265Janssen, M - 416, 541Janssens, T - 296Janthong, B - 346Jaramillo, T - 423Jariwala, B - 433Jarosz, P - 370Jaus, J - 232, 600Jawarani, D - 792Jayadevan, K - 903Jellison, G - 405Jenkins, P - 120, 264, 639Jensen, M - 884Jensen, S - 913Jeon, C - 906Jeon, J - 269, 341Jeon, M - 807Jeong, A - 892Jeong, H - 538, 539Jeong, J - 598, 603Jeong, Y - 385, 839Jester, T - 255Ji, J - 338Ji, K - 808, 966Ji, L - 249Jia, H - 82, 964Jian, C - 247Jiang, C - 406, 466, 486, 63, 978Jiang, D - 497, 642, 662JIMENEZ, C - 836Jimenez-Sandoval, S - 469Jin, H - 356Jin, J - 269Jin, X - 973Jindal, R - 6Jing-Shun, H - 380Jo, C - 862Jo, W - 892Jo, Y - 832, 837John, J - 216, 549, 809Johnson, J - 463, 95Johnson, L - 74, 76Johnson, M - 915Johnson, R - 0, 76Johnson, S - 732Johnston, K - 190Johnston, S - 11, 407, 412, 544, 65, 66Jones, G - 646Jones, K - 11, 407jones, K - 553Jones, R - 479, 55Jones, W - 619, 676Joo, J - 871Joo, M - 966Jordan, D - 292, 672, 673Joshi, P - 957Joshi, S - 944Jourdan, J - 242Jun, B - 631, 640Jun, Y - 832, 837Jung, D - 811, 813Jung, E - 0Jung, H - 787Jung, J - 414, 527, 543

214


Jung, S - 449, 455Junge, J - 90Juso, H - 109Jwo, W - 102Kabalan, A - 430Kabos, P - 393Kadakia, N - 810Kadota, N - 266Kailuweit, P - 34KAIZUKA, I - 43Kakihara, Y - 348Kale, P - 958Kalita, G - 28Kamada, R - 573Kamaras, K - 411Kamel, R - 726Kamikawa-Shimizu, Y - 208Kamler, C - 752Kaneshiro, J - 410, 604, 885Kanevce, A - 498Kang, B - 811Kang, D - 347Kang, G - 679Kang, J - 839, 852Kang, M - 540, 811, 812, 940Kang, S - 341, 739Kanjanachuchai, S - 437Kao, V - 246, 754Kappera, R - 0Karam, N - 35, 55, 857karger, E - 965Karim, K - 855Karp, J - 125Karpour, A - 321, 322Karsenty, A - 525KARST, N - 836Kasashima, S - 348, 349Kästner, G - 17Katayama, H - 268Kaufmann, C - 13Kauk, M - 605Kaul, A - 728Kaviany, M - 740Kawaguchi, Y - 50Kawashima, Y - 867, 968, 969kazimierczuk, M - 192Kazimierczuk, M - 695, 696Kazmerski, L - 206Kazmierowicz, C - 916Ke, Y - 841Keding, R - 791Keevers, M - 47Kellenbenz, R - 285, 34Kellock, A - 148Kelman, M - 334Kelzenberg, M - 219, 339Kempe, M - 68, 69Kendig, D - 408Kenny, R - 683, 684Kephart, J - 464Kerestes, C - 323, 757Kern, R - 56Kerr, L - 431Kessels, E - 789Kessels, W - 814Kessler, F - 13Kessler, M - 93Ketola, B - 70Keum, C - 356Keyes, B - 42

Khan, A - 641Khan, F - 15Khan, K - 368Khan, M - 516, 736Khatri, H - 608Khattak, C - 526, 545Khayyat, M - 868Khokhlov, P - 850Khonkar, H - 126Ki, H - 499Kijima, S - 50Kim, B - 356, 532, 675, 894Kim, C - 811, 813Kim, D - 499, 540, 598, 788, 808, 811, 844, 852, 940, 956Kim, G - 389Kim, H - 499, 540, 787, 824, 844Kim, I - 306, 328, 936Kim, J - 269, 306, 328, 381, 422, 539, 603, 740, 824, 852, 869, 883, 895, 896, 936Kim, K - 679, 897Kim, M - 456, 543Kim, S - 347, 381, 381, 499, 499, 540Kim, T - 389, 897Kim, W - 152, 603, 899Kim, Y - 385, 385, 839, 839, 844, 862, 897, 940, 957Kimball, G - 245Kimber, A - 255Kimerling, L - 361Kimmerle, A - 806Kimn, J - 733King, C - 772King, D - 258, 682King, J - 477King, R - 10, 35, 55Kini, R - 748Kinoshita, T - 793Kinsey, G - 189Kishimoto, Y - 759Kita, H - 135Kita, T - 428, 432, 435Kitahara, A - 268Kitazawa, N - 948Klaer, J - 149Kleinschmidt, S - 153Kline, D - 534Kling, R - 253Klinger, V - 285Klugius, I - 898Kneeburg, D - 122Knoll, E - 372Ko, H - 499Ko, J - 269Kobayashi, Y - 165Kobyakov, P - 180Koch, C - 240Kodama, T - 109Koehler, I - 155Koenig, D - 21Koga, K - 867, 968, 969Köhler, J - 934Kohli, S - 464Koirala, P - 211, 397Kojima, N - 286, 387, 388, 493, 494, 496, 501, 511, 512Kojima, O - 428, 432Kojima, T - 324


215


Komaki, H - 208Komori, K - 442Konagai, M - 176, 344, 346, 348, 349, 367, 805, 83, 951Kondo, M - 444, 656, 79, 82, 867, 971Konig, D - 438Kono, M - 130Koo, H - 835Kopecek, R - 184, 242, 325Kopidakis, N - 250, 372Kopp, F - 196Korbutiak, D - 950Kormanyos, K - 396Kosbar, L - 409Kose, M - 372Kösterke, N - 153Köstler, W - 56Kouchkarov, K - 469Kowalcyzk, J - 885Kowalczyk, J - 410, 604Koyama, K - 818Kozinsky, I - 361Kraemer, F - 294Kraiem, J - 326Krajangsang, T - 349Kranz, L - 236Krasowski, M - 264Krause, S - 149Krawczynski, M - 567Kray, D - 153Krc, J - 360Krebs, F - 251Kreinin, L - 525Krick, D - 167Krieg, A - 116Krishnan, G - 533Krishnan, R - 238, 905Krohn, J - 755Krokoszinski, H - 921Kroposki, B - 136, 256, 584Krotkus, A - 594Krueger, L - 169Krut, D - 35Ku, P - 749Kuciauskas, D - 856Kudrawiec, R - 858Kühnlein, H - 153Kuitche, J - 67, 713Kuk, S - 347Kukita, A - 262Kumagai, I - 761Kumar, A - 870Kumar, P - 922Kumar, R - 819Kumar, S - 128Kumar, U - 916Kunz, O - 143, 144Kuo, C - 223, 914Kuo, H - 514, 515, 821, 942Kuo, Y - 623, 959Kupchak, I - 950, 953Kuraishi, T - 86Kuriyagawa, S - 50Kurokawa, Y - 176Kurtz, S - 292, 487, 66, 672, 673, 69Kushiya, K - 50Kusko, M - 333Kuszmaul, S - 132, 716, 74Kutsukake, K - 186, 188Kuwahara, M - 148

Kwak, D - 598, 788Kwang-Sun, R - 833Kwapil, W - 113Kwietniak, K - 927Kwok, H - 962Kwon, D - 457Kwon, S - 540, 899Kyeong, D - 807Labrune, M - 310Lackner, C - 686Lacombe, J - 350Lad, R - 711Laghumavarapu, R - 224Lai, B - 112, 89, 964Lai, C - 485, 597, 616Lai, D - 327Lai, Y - 914Lalany, A - 849Lamers, M - 706Lan, C - 0, 690, 822Landi, B - 170Lane, P - 375Lang, N - 975Lantratov, V - 687Larionova, Y - 279Larrabee, D - 35, 55Larsen, B - 383Larsen, R - 371, 372Lau, K - 533, 923, 967Lauermann, T - 16Law, D - 35, 857Law, M - 792Lazarev, P - 850Lazcano, A - 621Le Bris, A - 22Le Carval, G - 443Le Tarte, L - 461Le, M - 0Lee, B - 433, 956Lee, C - 223, 386, 500Lee, D - 483, 598, 788, 896, 956Lee, E - 306, 328, 51, 527, 543, 906, 936Lee, G - 458, 960Lee, H - 302, 306, 306, 328, 328, 532, 808, 844, 844, 936, 936, 966Lee, J - 337, 347, 389, 458, 493, 501, 538, 676, 679, 741, 807, 811, 813, 845, 899, 899, 905, 938, 940, 960, 961Lee, K - 381, 385, 839, 883Lee, M - 509Lee, N - 892Lee, P - 302Lee, S - 247, 306, 328, 343, 434, 456, 899, 906, 936, 940Lee, T - 603Lee, W - 807Lee, Y - 871Lehman, J - 411Leighton, C - 452Leisch, J - 150, 234, 606Lelievre, J - 112Lemmi, F - 332, 334, 928Lennon, C - 459Lenox, C - 76Lentine, A - 773Leo, K - 129

216


Leou, K - 394Lepage, H - 443Lestrade, M - 478, 876Leubs, R - 464Leung, K - 473Levi, D - 412, 596, 65, 900Lewandowska, R - 418Lewis, N - 245Lewittes, M - 701, 804Ley, V - 31, 33, 657Li, B - 67, 698Li, G - 642Li, H - 175Li, J - 162, 211, 237, 335, 412, 502, 65, 846, 88, 900, 901, 962Li, L - 911Li, S - 490Li, T - 214Li, X - 272, 412, 460, 596, 625Li, Y - 267, 335, 374, 718Li, Z - 395, 478, 478, 804, 876, 876li, z - 777Liang, D - 490Liang, G - 615Liang, M - 394Liang, R - 173Liao, C - 690Liao, K - 373, 851, 854Liao, M - 0, 842, 917, 918Liao, W - 831, 838Liao, X - 340, 351, 578Liaw, B - 667Lien, S - 352Liliental-Weber, Z - 859Lim, D - 385, 458, 839, 960Lim, J - 832Lim, K - 269, 341Lim, S - 162, 502Lin, A - 224, 490Lin, C - 225, 226, 305, 353, 378, 386, 690, 822, 835, 919, 959Lin, D - 226Lin, H - 365Lin, M - 378, 386Lin, S - 394Lin, T - 365, 546Lin, Y - 378, 386, 745, 826Linares, P - 21Linsert, P - 120Liou, J - 919Lita, B - 461Littau, K - 930Little, R - 172, 700Little, S - 209, 879Liu, C - 799, 845Liu, D - 643Liu, F - 528, 664Liu, H - 0Liu, J - 361, 826, 927Liu, M - 119Liu, Q - 714Liu, S - 643, 649Liu, T - 220Liu, W - 148, 353Liu, X - 15, 35, 457, 55Liu, Y - 119, 462, 973Llorens, J - 221Lloyd, M - 250, 30, 841

Lo, K - 453Lochtefeld, A - 535, 757, 796Lochtenberg, B - 923Lockwood, M - 163Lof, R - 972Lonij, V - 572Loozen, X - 549Lord, K - 267, 664Lorentzen, J - 264, 639Lorenz, A - 809Lorenzoni, A - 586Lovvorn, C - 75Low, R - 329Loybal, L - 552Lu, C - 624Lu, D - 52Lu, J - 497, 642, 662, 799Lu, S - 758Lu, W - 690, 822, 919Lu, X - 503, 866Luan, H - 71Lucca, R - 716Luce, T - 124Luchetta, A - 696Lüder, T - 16Lui, H - 473Lund, E - 463Luo, C - 962Luque, A - 21, 221, 23, 280, 9Lushetsky, J - 39Luther, J - 874, 95Lutz, R - 32Lux-Steiner, M - 475Lyding, J - 64Lynass, M - 692Lytvyn, P - 955M, S - 633M., D - 638M., S - 633Ma, S - 41Ma, T - 343Macdonald, D - 114, 91Machado, M - 764Mack, P - 857Mack, S - 17, 240, 806, 920Maclean, R - 274MacWilliams, K - 945Mader, C - 330Madi, D - 357Madocks, J - 794Maes, C - 0Mahan, A - 963Mahn, J - 587Mai, Y - 964Maier, E - 872Makino, H - 607Makrides, G - 259, 574Malhotra, M - 219Malik, I - 722, 724, 751Malinovska, D - 594Mallajosyula, A - 29Mallick, T - 0, 778Mallory, S - 410, 885Mamizuka, M - 432Mandelboym, M - 278Mandoc, M - 789, 814Maness, L - 141Manginell, R - 368, 516Manglesdorf, D - 127Manivannan, V - 180, 464Mankelow, R - 723


217


Manning, J - 71Manno, M - 452Mansfield, L - 53, 900, 901, 907Manshanden, P - 19Mapes, M - 211, 396, 397Marcus, M - 745Margaria, T - 326Margetis, J - 459Maria, J - 801Mariayani, G - 224Marion, B - 677Marito, H - 0Marsen, B - 149Marsillac, S - 209, 608, 879Marstein, E - 537Marti, A - 21, 23Martí, A - 221, 280Martin, G - 513Martin, I - 145Martin, P - 64Martin, Y - 126Maruyama, E - 793Masakazu, S - 877, 96Masolin, A - 529Mason, A - 164Mason, T - 234Masui, H - 263Mathew, J - 713Mathew, L - 792Mathew, M - 355Matin, M - 742Matsubara, K - 208Matsui, T - 82MATSUKAWA, H - 43Matsumoto, M - 268Matsumoto, Y - 331, 753Matsumura, H - 818, 970Matsunaga, T - 867, 968, 969Matthew, M - 119Maximenko, S - 413, 661May, S - 746Mayandi, J - 816Mayer, M - 64Mayer, O - 692Mayes, K - 107Mazhari, B - 29Mazur, E - 745Mazzamuto, S - 181McCandless, B - 820McClure, E - 644Mccomb, B - 949McCurdy, P - 464McCutcheon, M - 354McDermott, D - 0Mcgehee, M - 117McGehee, M - 131, 222, 439McIntosh, K - 214, 530, 531, 70, 815McIntyre, P - 490McLain, C - 120McMahon, W - 487McMuldroch, S - 668McNamarah, C - 582McNeil, D - 0McQuiston, E - 152Meader, A - 169Mehrotra, A - 637, 645Mehta, V - 939Meier, D - 930Meier, R - 294

Meinhardt, C - 299, 929Meisel, A - 332, 928, 941Meissner, D - 872Meitl, M - 122Melinger, J - 375Melkote, S - 946Mellikov, E - 474, 594Melton, A - 118Menard, E - 122Mendes, E - 712Mendoza-Pérez, R - 471Meng, Z - 962Menkoe, M - 319, 800Menossi, D - 181Merrill, J - 44Mertens, R - 198, 216, 529, 549, 795, 937Mesa, F - 601Mesropian, S - 35, 857Messenger, S - 261, 413, 646, 647, 661Metacarpa, D - 179, 54Metin, B - 51Mette, A - 312Metzger, W - 498Meusel, M - 285, 56Meusinger, K - 156Meyer, K - 921Micard, G - 89Michael, S - 648Michel, J - 361Michel, R - 904Midgett, A - 95Midtgård, O - 691Miedaner, A - 611, 890, 943Mifsud, P - 594Mikeska, K - 804Miki, S - 392Miller, D - 69Miller, E - 410, 604, 885Mills, M - 886Min, D - 0Mine, T - 446Minemoto, T - 622, 902Ming-Yi, L - 380Minkin, L - 768Mints, P - 593Minuto, A - 781Miranda, D - 965Mise, T - 609, 86Mishra, R - 922Mishra, U - 505Misiewicz, J - 858Misumi, K - 148Mitchell, L - 257Mitchell, R - 42Mittal, S - 957Mittelstrass, D - 197, 419Mittman, J - 33Mitzi, D - 148Miyadera, T - 376Miyajima, S - 176, 344, 346, 348, 349, 367, 805, 83, 951Miyamoto, M - 818Miyano, T - 50Miyashita, N - 504Miyazaki, H - 948Mizukoshi, K - 12Mizuno, K - 82Modisette, D - 368Mohamed, H - 218Mohr, C - 800

218


Moia, D - 252Mokri, A - 774Molina, S - 221Monakhov, E - 816Monden, M - 392Mondon, A - 298Monfette, A - 370Montanez-Ortiz, W - 301MONTES, L - 775Montgomery, K - 873Moon, B - 0, 532Moon, T - 966Moon-Jin, H - 833Morales, C - 387, 388Morante, J - 415, 888Morel, D - 465, 467, 472, 476, 903Morhenn, H - 90Mori, M - 442Moricone, T - 68Morimoto, J - 948Morimoto, T - 50Morioka, C - 650Morioka, T - 435, 441Moro, L - 533, 923, 967Morozov, E - 850Morris, R - 697Morrison, A - 769Morse, M - 674Morseman, J - 120Moskito, J - 904Moss, M - 120Mott, J - 519Mottaghian, S - 733Mottaghizadeh, A - 0Moumen, N - 126, 218Mount, G - 904Moura, T - 965Moutinho, H - 334, 406, 466, 88, 963Movla, H - 0, 0, 0Moynihan, M - 243, 910Mucha, J - 590Mudaliar, S - 589Mudigonda, S - 297Mueller, N - 156Mueller, T - 156, 382Mughal, H - 763Mukashev, B - 534Mulder, P - 287Müller, J - 330Mulligan, W - 190, 71Mullin, J - 329Mundt, M - 587Mungekar, H - 922Munoz, D - 18Mur, P - 18, 443Murakami, A - 660Muralibabu, B - 436Muralidharan, K - 229Murata, K - 268Murcia, C - 535, 796Muric-Nesic, J - 193, 723, 784Murison, R - 53, 907, 926Muska, K - 605Mussabek, G - 743Muthusamy, M - 436Mutitu, J - 536Myers, H - 210Naczas, S - 810Nagahashi, M - 50

Nagai, H - 761Nagaich, K - 617Nagaoka, A - 626, 629Nagar, A - 533Nagasaka, K - 726Nagel, J - 744Nagyvary, J - 59Naik, D - 717Nair, P - 27Nakada, T - 609, 86Nakagawa, M - 268Nakahara, K - 867, 968, 969Nakaido, K - 109Nakajima, K - 186, 188Nakamura, K - 109Nakamura, S - 595Nakamura, W - 968, 969Nakanishi, H - 208Nakano, Y - 58, 877, 96, 98Nalaskowski, J - 409, 927Nam, C - 843Nam, H - 832Nam, W - 220Namjil, E - 665Nardes, A - 372Naruush, E - 665Nascimento, L - 563, 564Naseem, A - 211Nash, L - 287Nasr, M - 354Natori, M - 387, 388Nawaz, M - 537Nayak, D - 51Neidert, M - 800Nekarda, J - 154, 791Nelson, B - 0Nelson, L - 76Nemac, F - 594Neubauer, R - 791Neufeld, C - 505Neuhaus, H - 197Neumayer, D - 927, 957Newbury, J - 927Newhouse, P - 150Newlander, C - 639Newman, B - 745, 89Newman, F - 33Newmiller, J - 231Ngo, V - 688Nguyen, N - 18Nichol, S - 242Nielsen, Ø - 913Nielson, G - 288, 309, 773Nievendick, J - 116Niki, S - 12, 208, 442, 650Niklas, J - 197, 419Nikniazi, A - 0Nikulin, V - 743Nikumb, S - 53, 907Nishi, S - 387, 388Nishikawa, T - 970Nishio, M - 754Nishioka, K - 506, 776Nishiwaki, S - 151Niu, X - 46Nocerino, J - 649Nomura, A - 756Nomura, T - 266Nordseth, Ø - 913Norheim, L - 913Norman, A - 486Norman, K - 618


219


Norris, A - 70, 702Norton, M - 684Noufi, R - 272Novak, J - 54Novikov, S - 859Nowlan, M - 700Nozaki, Y - 165, 262Nozik, A - 874, 95Nukala, H - 463Numakami, O - 442Nursam, N - 215, 817Nussbaumer, H - 153Oakvath, J - 94O’Brien, C - 168O’Brien, K - 162O’Connor, C - 243, 910Oener, S - 295Oesterlin, P - 320Ogawa, H - 262Ogo, H - 379Ogomi, Y - 130Ogura, A - 324Oh, D - 306, 328, 936Oh, H - 807Oh, J - 233Oh, K - 538, 539Oh, S - 883O’Hayre, R - 611, 747Ohdaira, K - 818, 970OHIGASHI, T - 43Ohl, S - 90Ohshima, T - 650, 655, 656Ohshita, Y - 158, 286, 324, 493, 494, 496, 501, 511, 512Ohta, J - 447Okada, Y - 24, 281, 283, 435, 441, 445, 504Okamoto, A - 262Okamoto, Y - 948Okanda, M - 309Okandan, M - 288, 773Okano, Y - 442Okumura, T - 651Olaisen, B - 816Olavarria, W - 487, 510Olchowik, J - 590, 924Olejnícek, J - 752Olias, E - 565Oliva, E - 285Olson, D - 30, 371, 372, 841Olson, J - 470, 57Olson, K - 643O’Neill, B - 139Ong, D - 327Ono, S - 188Oomen, G - 265Oon, C - 327Opila, R - 118, 304, 503, 573, 757, 866Ortega, M - 331Ortega-Cervantes, G - 471Ortiz-Rivera, E - 712Oruganti, R - 718Osborn, D - 561Oshima, M - 610Oshima, R - 283, 435, 441, 445Oslon, D - 250Ostapenko, S - 946Ostermann, T - 686Osterwald, C - 673O’Sullivan, B - 925

Ota, Y - 506, 776Otani, K - 558, 665, 678Ou, Y - 352Øvrelid, E - 521Owczarczyk, Z - 371, 372Ozanne, A - 18Paak, S - 922, 945Packa, J - 333Page, M - 534, 552, 62Palekis, V - 467, 472, 476Palfy, M - 594Pan, N - 513Panarello, T - 53, 907Panchal, A - 355Pandey, S - 130Pangan-Okimoto, K - 477Pankov, J - 621Pankow, J - 748Pantsar, H - 232, 600, 926Panyakeow, S - 437Papa Rao, S - 927Papathanasiou, N - 336Paponneau, F - 562Pappan, J - 32Parekh, R - 483Parikh, S - 922Parilla, P - 747, 748, 963Park, C - 389, 844, 905Park, D - 532, 839Park, J - 389, 527, 543, 543, 603, 757, 869, 905Park, K - 788, 966Park, M - 839Park, N - 883Park, S - 269, 337, 356, 381, 540, 679, 811, 813, 839, 852, 906, 906, 940Park, Y - 869Parker, J - 423Pasquarelli, R - 611, 943Patangia, H - 719Patel, S - 482Pathak, M - 577, 819Patiño, J - 576Patnaik, B - 230Patra, J - 680Patrin, J - 179, 54Patterson, R - 21, 438Pattnaik, S - 338Paudel, H - 746Paudel, N - 15, 239, 457Pawlak, B - 296Payne, A - 930Payne, D - 358Peake, G - 516Pekker, A - 411Pelletier, D - 326Peloso, M - 681Penatta, C - 643Pepin, J - 804Perdomo, R - 585Perez, J - 533, 923, 967Perez-Rodriguez, A - 415Pérez-Rodríguez, A - 888Periasamy, P - 747Perkins, J - 234, 248, 410, 606, 611, 619, 841Pern, F - 272, 907Pern, J - 53, 621Perng, D - 612Perny, M - 333Perrenoud, J - 236

220


Peshek, T - 596Peter, K - 184, 325Peter, P - 652Peters, C - 222Peters, S - 329Peterson, D - 35, 631Peterson, E - 384Pethe, S - 613, 728Pfeiffer, K - 179, 54Pfeiffer, M - 129Pfitscher, P - 563, 564Pham, T - 241Phang, S - 114, 91Philipps, S - 285Phok, S - 748Piao, H - 461Pichner, R - 382Pickett, E - 439, 490Pien, P - 479, 55Pietka, G - 267, 664Pietruszko, S - 588, 594Pillai, R - 632, 858Pinarbasi, M - 183, 51Pinaud, B - 423Pingel, S - 709Placencia, D - 127Plourde, C - 427Pluym, T - 288Podraza, N - 49Poepelmeier, K - 234Polly, S - 282, 427, 495, 635, 94Polman, A - 175Polupan, G - 976Ponnekanti, H - 949Ponomarev, M - 359Poodt, P - 235Pookpanratana, S - 149, 15Poortmans, J - 198, 216, 296, 529, 549, 72, 795, 798, 809, 925, 937Popescu, L - 325Poplavskyy, D - 334, 928Popovich, V - 416, 541Porada, O - 955Posbic, J - 255, 277Posthuma, N - 198, 296, 795, 925, 937Potts, T - 614Pourkamali, S - 547Powell, N - 70, 702Powers, L - 231Prabhakar, A - 148Prabhakar, T - 468Prabukanthan, P - 752Prajapati, V - 216, 809Prasad, B - 819Prathap, P - 357Prather, D - 536Pratt, L - 682Pravettoni, M - 683, 684Preu, R - 17, 240, 320, 791, 800, 806, 920, 931Proenneke, L - 703Ptak, A - 65Pulver, D - 290Pulver, S - 292, 572Pulwin, Z - 483Pysch, D - 299, 929Pyzyna, A - 927Qiao, Q - 377, 846Qiu, K - 758

Qiu, Y - 72, 925Quintana, M - 587Quintilla, A - 898qunwu, h - 777R.S., E - 633Raabe, B - 16, 300Radivojevic, I - 843Raffaelle, R - 170, 282, 427, 630, 94Rafique, S - 736Raghavan, P - 526Raghuraman, B - 67Rahm, A - 13Rahman, D - 641Rahmati, A - 0Rai, D - 355Rajapaksha, C - 637, 669Raman, A - 25Ramanathan, S - 155, 217Ramappa, D - 329Rand, B - 252Rand, J - 297, 311Ranjan, V - 209Ransome, S - 569Rao, R - 792RAPENNE, L - 836Rapolu, K - 542, 930Rar, A - 247Ratcliff, E - 127Rath, T - 872Rathi, M - 507Rattanathammaphan, S - 437Raudoja, J - 474Ray, B - 27Razykov, T - 469Reatti, A - 192, 695, 696Rech, B - 143, 336Reddy, S - 724, 819Reed, B - 653Reedy, R - 334Reese, M - 248, 250, 68Regaard, B - 600Reichel, C - 244Reichertz, L - 246, 754Rein, S - 187Reinders, A - 265, 581Reinwand, D - 931Reitenbach, H - 319Rekow, M - 53, 907, 926Ren, Y - 214, 215, 817Rendering, H - 235Rentsch, J - 116, 243Repins, I - 11, 234, 407, 65, 900, 901Repmann, T - 80Resch, R - 0, 108, 7Resnick, P - 288, 309Retzlaff, M - 800Reusch, M - 244Reuter, K - 148Reuter, M - 703, 868REY, G - 836Rey-Stolle, I - 161Riazia, M - 490Ribeyron, P - 18Ricalde-Cab, L - 570, 583, 699Richards, E - 591Richardson, I - 416, 541Richardson, W - 685Richter, A - 214, 932


221


Richter, P - 301, 933Ridler, T - 910Riede, M - 129Riel, B - 289Riepe, S - 187Riley, D - 258Rim, S - 674Ringel, S - 480, 489, 661Rinio, M - 112Ripalda, J - 221Rivera, A - 221Roach, D - 804Robbelein, J - 795, 925Roberts, B - 749Roberts, J - 1Robie, S - 904Robinson, K - 720Roca i Cabarrocas, P - 310Roche, J - 568Rocheleau, R - 667Rockett, A - 462, 64, 879Röder, T - 934Rodiek, J - 560Rodriguez, Y - 470Roesener, T - 285Rogers, B - 596Rogers, C - 62Rogojina, E - 334Rohatgi, A - 155, 217, 307, 312, 405, 812Rohr, C - 913Rohwer, H - 846Roitberg, M - 520Romanuk, B - 955Romanyuk, Y - 151Romeo, A - 181Romeo, N - 181Romero, M - 145, 334, 510, 513, 61Rorrer, G - 0, 40Rösch, R - 253Rose, D - 190Rosenits, P - 196Rosseel, E - 296Rossnagel, S - 927, 957Rotaru, C - 475Rothschild, A - 549, 809Rotter, T - 516Roufberg, L - 163Rouhani, K - 35, 640Rounsaville, B - 312, 812Roussel, B - 418Roybal, L - 145Rozenzon, Y - 278Rozeveld, S - 886Ruden, P - 755Ruiz, C - 161Rummel, S - 599Rupnowski, P - 544, 545Rusu, M - 475Ruther, R - 563, 564Ryabova, E - 722, 724, 751Ryningen, B - 242Ryu, H - 458, 960, 961Sabnani, L - 724Sadana, D - 868Sadeghimakki, B - 750Saetre, T - 691Saf, R - 872Sahlstrom, T - 654Sai, A - 158Sai, H - 656, 79

Sailer, M - 153Saint John, D - 49Saito, K - 971Saito, M - 655Saito, T - 548, 753, 756Saito, Y - 135Saitoh, T - 797Sakai, J - 376, 379Sakai, S - 82Sakata, H - 793Sakurada, Y - 506Sakurai, T - 208Salas, V - 565Salupo, C - 146Salvetat, T - 18Saly, V - 333Sambandam, S - 247, 637Sambasivan, S - 602Sampath, W - 180, 464Sams, M - 686Samuels, S - 701Samukawa, S - 283Sanchez, C - 288Sanden, M - 48Sander, M - 417Sandoval, S - 368, 516Sandstrom, R - 126Sanford, N - 393Sang, B - 52Sangiorgi, E - 555Sanjurjo, A - 533, 923, 967Sankaralingam, S - 853Sano, N - 24Santana, R - 965Santbergen, R - 173Sarau, G - 159, 418Sarkar, A - 752Sarkar, D - 792Sarmah, N - 778Sarmiento, T - 490Sasaki, K - 109Sasaki, T - 158, 266Sastré-Hernández, J - 471Sastry, A - 909Sato, H - 867Sato, S - 650, 656Saucedo, E - 415Saxena, A - 819Sazonov, A - 342Scardera, G - 334, 928Scarpulla, M - 463, 744Scharf, M - 697Scheit, C - 13Schermer, J - 287, 481Schetter, C - 298, 929Schindel, K - 591Schlager, J - 393Schlatmann, R - 336Schmidt, J - 213, 402, 403Schmidt, M - 688Schmidt, T - 21Schmiga, C - 921Schneider, D - 618Schock, H - 13, 149Schoendorf, M - 26Schoenfelder, S - 295Scholz, S - 16Schönfelder, S - 159Schoonderbeek, A - 253Schoop, U - 2, 908Schroeder, J - 80Schropp, R - 175, 972, 973

222


Schubert, B - 149Schubert, M - 113, 196, 259, 313, 400, 401, 574Schuegraf, K - 949Schuh, N - 180Schüler, N - 197, 419Schuler, S - 2, 908Schülke, P - 13Schultz, D - 779Schuur, J - 646Schwartz, B - 224Schwartz, G - 129Schwartz, R - 491, 492, 735, 785Schwarz, J - 735Schweizer, S - 417Schwertheim, S - 156, 382Scott, M - 625, 88Sculati-Meillaud, F - 360Scurtu, R - 475Seacrist, M - 544Sear, I - 734Seel, S - 122Segal-Peretz, T - 847Seguin, R - 789Seidel, J - 257Seiler, S - 639Seitz, S - 931Sekimoto, T - 268Sellami, N - 0Selvamanickam, V - 247Selvamanikham, V - 637Semans, S - 860Semonin, O - 874, 95Sen, S - 440Senanayake, P - 224Seo, M - 341Seol, M - 598Seong, T - 603Seraphin, S - 450Seren, S - 90Sergeev, V - 782Serra, J - 517Serrano, G - 712Serri, L - 192, 695, 696Seshan, C - 508, 780Sestak, M - 146, 211, 396, 397Seto, S - 595Seu, S - 0Severin, D - 949Seyedmohammadi, S - 935Seymour, E - 720Seyrling, S - 151Sfeir, M - 843Shafarman, W - 152, 85, 889Shah, A - 360Shah, S - 928, 941Shaheen, S - 841Shaikh, A - 935Shakouri, A - 408Shalyt, E - 615Shangguan, T - 794Shanmugam, M - 825, 829, 830, 834Shanmugam, V - 327Shaozhen Xiong, S - 962Shapiro, J - 224Sharma, K - 48Sharma, P - 230, 440Sharma, S - 631, 640

Sharma, U - 904Sharps, P - 31, 32, 33, 657Shcherbyna, L - 976Shea, S - 542Shen, D - 467, 472Sheng, P - 882Sheng, X - 361Shepherd, F - 289Sher, M - 745Shet, S - 544, 742Shi, G - 247, 544Shi, S - 536Shi, Z - 729Shiao, J - 690Shibata, H - 208Shibata, Y - 376Shieh, J - 345Shih, I - 210Shih, W - 597, 616Shim, C - 844Shim, J - 306, 328, 936Shim, W - 385, 839Shimada, T - 262Shimazaki, K - 165, 656Shimura, H - 671Shin, C - 788Shin, H - 500, 862, 966Shin, K - 449Shin, R - 892Shin, Y - 895Shinmiya, M - 628Shinohara, W - 268Shipkovs, P - 594Shiratani, M - 867, 968, 969Shishido, T - 756Shisler, W - 67Shiu, S - 225, 226, 378, 386Shkrebtii, A - 404, 950, 953Shoieb, S - 450Shoji, Y - 435, 441, 445Shrestha, M - 827, 828Shrestha, S - 21, 448Shreve, K - 323, 535, 796Shu, B - 820Shub, M - 145Shvarts, M - 687Siaw, F - 766Siefer, G - 160Sigdel, A - 30, 841Silvestre, S - 280, 571Simmonds, P - 509Simoen, E - 198Simon, J - 509Simonds, B - 974Simpson, L - 248Sin, M - 824Singh, C - 355Singh, P - 430, 542Singh, R - 944Singh, S - 577, 937Sinke, W - 111Sinton, R - 194Sivakumar, K - 957Sivec, L - 978Sivoththaman, S - 750Skarp, J - 236Skelton, D - 526Skinner, W - 329Skryabin, I - 723, 783Skumanich, A - 722, 724, 751Slafer, D - 338


223


Slaoui, A - 357Slaymaker, L - 884Slonim, A - 704Slonim, M - 704Smeenk, N - 481Smentkowski, V - 461Smets, A - 46Smith, B - 211, 434Smith, D - 190, 71Smith, G - 384, 657Smith, R - 257, 292, 673, 861Smith, S - 420, 464Snyder, N - 654So, J - 566So, W - 527, 543Sohn, S - 456sohrabi, f - 0Sohrabi, F - 0, 0Soiland, A - 184Solanki, C - 303, 440, 589, 727, 909, 958Soler-Bientz, R - 570, 583, 699Somberg, H - 694Son, C - 940Son, J - 362Søndenå, R - 816Song, B - 956Song, G - 278Song, J - 337, 540, 679, 813, 813, 938Song, K - 620, 880, 896Song, S - 617Sontheimer, T - 143Sonvilla, P - 588Sopian, K - 368, 469, 516Sopori, B - 544, 545, 939Sordyl, M - 590Souche, F - 18Soukup, R - 752, 884Specht, J - 931Speck, J - 505Spencer, S - 370Spiegelman, J - 893, 920Spitzer, M - 705SpringThorpe, A - 289Staiger, C - 618Stan, M - 31, 32, 33, 657Stanbery, B - 52, 890Starikov, D - 632, 858Staub, J - 370Stavrinou, P - 1Steen, S - 957Steenbergen, E - 162Stefanakos, L - 472Stefananakos, E - 467Stein, J - 255, 258, 74Steiner, M - 285, 486, 487, 510, 957Steirer, K - 250, 30Stella, P - 658Stelzer, F - 872Stempki, M - 273Stephens, S - 42Sterba, J - 0Stern, O - 692Stewart, M - 922Stone, K - 189Stone, P - 754Stone, S - 688Stoss, W - 2, 908

Stradins, P - 145, 433, 45Street, A - 164Street, R - 26Stribling, R - 164Strickler, D - 396Strobel, M - 567Strobl, G - 56Strossman, G - 904Stückelberger, M - 360Stuewe, D - 931Sturm, M - 781Stüwe, D - 791Stylianides, A - 594Su, C - 32Su, T - 267, 664Su, Y - 485Subramani, M - 949Suemasu, T - 753, 756Suganthi, L - 783Sugaya, T - 442, 650Sugianto, A - 157Sugimoto, H - 50Sugimura, E - 315, 548, 797Sugiyama, M - 58, 98Suh, C - 619, 676Suh, J - 620, 880Sullivan, J - 745Sullivan, P - 329Sun, J - 386, 979Sun, W - 352, 485, 546, 786Sundaram, A - 247Sundaramoorthy, R - 11, 234, 272, 407, 621Surana, K - 443Surve, S - 193, 784Surya, C - 473Sutton, S - 164Suzuki, H - 158, 286, 493, 494, 496, 501, 511, 512Svrcek, V - 444Swaminathan, K - 480Swanson, R - 190Sweatt, W - 773Symko-Davies, M - 201, 42Syperek, M - 858Syre, M - 816Syvertsen, M - 521Taboada, A - 221Tachibana, T - 324Taguchi, M - 793Tai, E - 928Taima, T - 376, 379Taira, S - 793Tajima, M - 262, 660Takahashi, E - 613Takahashi, M - 109, 165, 36Takahashi, T - 317, 622Takakura, H - 902Takamoto, T - 109, 165, 286, 36Takata, A - 435, 441, 445Takayama, T - 797Takeda, Y - 655Takele Beyene, H - 359Takemo, Y - 627Takemoto, Y - 628Takeuchi, Y - 82Takiguchi, H - 948Takihara, M - 622Tamboli, A - 219Tamendarov, M - 534

224


TamizhMani, G - 233, 711, 713Tamizhmani, G - 67Tan, C - 327Tan, J - 114Tan, W - 826Tan, Y - 327Tanaka, M - 268Tanaka, T - 512, 754Tanaka, Y - 50Tang, H - 742Tang, J - 278, 949Tangmettajittakul, O - 437Tangstad, M - 522Tani, A - 315, 398, 548, 797Tanner, D - 411Tao, J - 0Tao, M - 81, 864Tao, Y - 144Tarasov, I - 946Tark, S - 540, 811, 940Tashiro, R - 626Tatavarti, R - 513Tate, K - 312Tathgar, H - 242Taurbayev, T - 743Taurbayev, Y - 743Tayahi, M - 0, 0Taylor, E - 635, 659Taylor, L - 659Taylor, P - 974Teatro, T - 404, 950, 953Teckhaus, D - 253Teeter, G - 150, 383Tejwani, R - 727Tello, J - 576Tenent, R - 383Teodoreanu, D - 594Teplin, C - 145, 62Terada, N - 208Terakawa, A - 268Terheiden, B - 16Terlinden, N - 789, 814TERNON, C - 836Terry Jr., F - 900Terry, M - 928, 941Terwilliger, K - 66Tessema, M - 14Thainoi, S - 437Thakkar, N - 572Theelen, M - 235Thøgersen, A - 913Thombare, S - 490Thompson, C - 293, 85Thompson, K - 886Thompson, T - 450Thomsen, E - 723Thony, P - 443Tiffany, S - 243Timmo, K - 474Timmons, M - 290Timmreck, R - 129Timo’, G - 781Timoshenko, V - 743Timothy, G - 460Tischler, J - 1Tiwari, A - 151, 236, 881, 888Tjahjono, B - 157Tjengdrawira, C - 706, 721To, B - 11, 272, 407, 748, 900, 901, 963

Todorov, T - 148Tois, E - 19Tokioka, H - 346Tokuda, T - 595, 626Toledo, N - 505Tomasulo, S - 509Tomlin, N - 411Tomura, N - 970Tong, C - 102Torardi, C - 804Torchynska, T - 976Torrey, E - 755Totir, G - 409, 927Tousifar, B - 547Townsend, T - 231Toxopeus, M - 581Toyoda, K - 263Toyota, H - 262, 660Tracy, C - 670Träger, A - 153Tran, B - 477Trassl, R - 931Trautz, K - 639, 646Treiber, L - 21Tremblay, E - 125Treptow, D - 313Trimmel, G - 872Trudell, D - 66Trujillo, R - 278Truong, Q - 414Tsai, C - 365, 597, 616Tsai, F - 363Tsai, H - 917Tsai, M - 121, 514, 515, 612, 821, 942Tsai, T - 515Tsai, Y - 514, 942Tsao, C - 914Tsao, P - 99Tseng, B - 623Tseng, C - 500Tseng, P - 485, 514, 515, 821, 942Tseng, W - 835Tsuchiya, R - 446Tsujii, S - 315, 548, 797Tsukamoto, J - 379Tsuno, Y - 671Tsunomura, Y - 793Tsuru, H - 629Tsuruga, S - 82Tu, L - 485Tu, W - 343Tulevski, G - 218Tulloch, W - 307Tuminello, F - 513Tung, F - 975Turevskaya, E - 857Turkevych,, I - 444Turmagambetov, T - 534Turnar, J - 742Turner-Evans, D - 219Turowski, M - 635Tutuc, E - 218, 399Tuzun, O - 357Tynan, J - 412Ueda, Y - 135Uhl, A - 881, 888Uhrich, C - 129Ullah, S - 736Ullal, H - 42, 469Umeno, M - 28


225


Underwood, J - 943Upadhyaya, A - 217Upadhyaya, H - 469Uppal, P - 768Urbanetz Junior, J - 563, 564Uribe, R - 647Uruena de Castro, A - 809Urueña, A - 798Usagawa, J - 130Usami, N - 186, 753, 756Usami, U - 188Uzaki, K - 130Uzawa, R - 348Vaes, J - 529Valdivia, C - 289, 762Vallêra, A - 517Vallon, S - 357van Bommel, C - 973van de Lagemaat, J - 383van de Sanden, M - 147, 359, 814van de Sanden, R - 789van Deelen, J - 235van der Werf, K - 973van der Wilt, P - 72Van Dijken, J - 849Van Gestel, D - 72van Hest, M - 234, 611, 841, 890, 943Van Kerschaver, E - 198, 795van Kessel, T - 126van Riesen, S - 56Van Scheppingen, R - 193, 784VanSant, K - 42Varadan, V - 249Varema, T - 474, 605Varghese, T - 31, 33, 657Varlamov, S - 144Vasilyev, L - 402, 403Vasquez, J - 51Vasylyev, S - 782Vasylyev, V - 782Vatavu, S - 475, 476Vázquez, M - 325Veettil, B - 21, 438Veith, B - 213Vela, N - 725Veldman, D - 721Veneman, P - 127Verebelyi, D - 2, 908Verma, L - 362, 870Verma, R - 151Vermang, B - 549, 809Verschuuren, M - 175Verwaal, W - 416Vesvikar, C - 944Viana, T - 563, 564Vichiconti, J - 927Vigil-Galán, O - 471Vijaya, G - 97VIllela, D - 229Vinod, P - 550Vitanov, P - 594Vivar, M - 193, 783, 784Vivas Hernández, A - 976Voderadska, Z - 594Vogl, M - 92Volobujeva, O - 605von Maydell, K - 350

von Roedern, B - 42Voropayev, A - 67Voss, S - 134Vosters, G - 861Vroon, Z - 235Wacaser, B - 868Wada, O - 428, 432Wagenmann, D - 791Wagner, D - 771Wagner, M - 113Wagner, S - 220Wagner, W - 122Wakisaka, Y - 622, 902Wakita, K - 28Walczak, A - 920Waldhauer, A - 71Wallis, T - 393Walsh, A - 875Walter, D - 193, 196, 784Walters, K - 180Walters, R - 1, 120, 261, 264, 4, 413, 639, 646, 647, 661Walukiewicz, W - 246, 754, 859Wan, C - 305Wan, Y - 554Wan, Z - 977Wandhare, R - 715Wang, B - 431Wang, C - 352, 597, 616Wang, D - 215, 369, 552, 730Wang, G - 979Wang, H - 514, 515, 942, 964Wang, I - 378Wang, J - 363, 551, 865Wang, K - 218, 954Wang, L - 119, 497, 554, 642, 904Wang, Q - 0, 117, 177, 412, 453, 552Wang, R - 758Wang, S - 949Wang, T - 0, 51Wang, W - 0, 127, 917, 949Wang, X - 283, 689Wang, Y - 305, 323, 757, 760, 770, 877, 96, 98Wangperawong, A - 477Wanlass, M - 288, 488, 507, 510, 513Ward, S - 552Warner, J - 261, 413, 647, 661Warrick, W - 0Warta, W - 113, 196, 400, 401Washio, H - 109Wasson, K - 182Watabe, H - 262Watanabe, K - 446, 58Watanabe, Y - 948Watjanatepin, N - 364Wdowiak, B - 156Webb, J - 182Weber, K - 214, 215, 817, 823Weber, T - 685Weeber, A - 19Wei, C - 369, 597, 979

226


Wei, S - 212, 365, 454, 546, 875Weidman, T - 922, 945Wei-Fang, S - 380Weinhardt, L - 149, 15Weinzerl, H - 167Weiss, S - 596Weiss-Wallrath, H - 329Welser, E - 285Wen, Y - 877, 96, 98Weng, J - 179, 54Wenham, S - 157, 321, 322, 328Wen-Hao, W - 380Werner, F - 213Werner, J - 259, 574, 703, 934Western, N - 157Wheeldon, J - 289, 762Wibowo, A - 513Widjonako, N - 841Widjonarko, N - 30Widmer, J - 129Wiedeman, S - 2, 908Wieland, K - 14, 239, 457Wiese, S - 294Wijekoon, K - 945Wilcox, D - 182Wilcox, J - 491, 492, 735, 785Wilks, R - 149Williams, D - 860Wilson, K - 71Wilt, D - 654Winkler, M - 709, 745Wise, W - 640Witting, K - 80Wittner, M - 685Wohlgemuth, J - 277, 711Wojtczuk, S - 290Wolf, A - 17, 240, 920Wolford, D - 663Wolter, K - 294Wong, C - 766, 767Wong, D - 301, 933Wong, F - 263Wong, H - 423Wong, J - 144, 47Wong, S - 335Woo, R - 35Wood, C - 886Woodall, J - 873Worrel, C - 267, 664Wotke, E - 17, 240Wronski, C - 46, 49Wu, C - 500, 624, 840, 882, 962Wu, D - 690, 822, 912Wu, H - 946Wu, J - 0, 223, 831, 838, 840Wu, M - 579, 642, 662Wu, P - 612, 975Wu, S - 366, 554Wu, W - 386Wu, Y - 597, 616Wünsch, F - 331Würfel, P - 681Würz, R - 13Wuu, D - 352Wynands, D - 129Xiang, X - 340, 351, 578

Xiao, L - 374Xiao, Y - 478, 876Xie, B - 533, 923Xie, Y - 377, 846Xiong, K - 758Xiong, S - 369, 979Xiong, X - 247Xu, B - 930Xu, D - 459Xu, H - 578, 578Xu, J - 434, 497, 642Xu, T - 118, 846Xu, X - 267, 664Xu, Y - 117, 177, 552Xu, Z - 278Yachi, T - 708Yagi, S - 281Yagioka, T - 50Yaklin, M - 618Yamada, A - 12, 176, 208, 348, 805, 951Yamada, S - 176Yamada, T - 607Yamaguchi, H - 109Yamaguchi, K - 447Yamaguchi, M - 158, 286, 324, 387, 388, 493, 494, 496, 501, 511, 512, 634, 641Yamaguchi, Y - 130Yamamoto, N - 607Yamamoto, T - 607Yamanari, T - 376, 379Yamasaki, Y - 188Yamashita, I - 283Yamashita, K - 595Yambem, S - 373, 851Yan, B - 267, 664, 974, 978Yan, J - 490Yan, X - 374, 377, 482Yan, Y - 406, 553, 625, 65, 742, 978Yang, C - 343Yang, D - 554Yang, F - 395Yang, H - 254, 362, 707, 758, 870Yang, J - 267, 664, 938, 978Yang, K - 458, 960Yang, L - 59Yang, S - 269Yang, W - 149, 957Yano, H - 548Yao, Y - 448Yaoming, W - 0Yasasvi, G - 717Ye, D - 964Yeh, C - 363Yeh, D - 343Yeh, F - 690, 822Yeh, Y - 546Yelundur, V - 405Yew, T - 766Yi, J - 458, 961yiping, w - 777Yoo, H - 896Yoo, J - 566Yoo, S - 341, 956Yoon, H - 899Yoon, J - 603Yoon, K - 337, 449, 455, 603, 679Yoon, S - 540


227


Yoon, W - 966Yordanov, G - 691Yoshida, A - 109Yoshida, K - 24Yoshida, T - 759Yoshida, Y - 376, 379Yoshino, K - 595, 610, 626, 627, 628, 629Yoshitake, T - 595Yoshiyama, T - 12Yoshizuru, K - 627Yost, V - 553You, D - 554Young, D - 145, 334, 528Young, M - 150, 237, 249, 461, 487, 625, 87, 901Young, R - 309Young, T - 765Youtsey, C - 513Yu, B - 566Yu, C - 278Yu, G - 566, 578Yu, H - 335Yu, K - 246, 754, 859Yu, P - 121, 345, 514, 515, 552, 738, 786, 821, 848, 942Yu, S - 365, 499, 546Yu, T - 532Yu, Z - 117, 177, 25, 490Yuan, H - 412, 553Yuan, M - 148Yue, G - 267, 978Yu-Hong, L - 380Yun, J - 449, 455, 869, 896, 899Yunaz, I - 344, 346, 348, 349, 367, 83Yunus, A - 541Yu-Rim, B - 833Yuwen, Z - 0Zabielski, K - 590Zachmann, H - 13Zahler, J - 277Zaidi, S - 368, 516Zajac, K - 13Zakaria, A - 35Zanatta, A - 952Zanuccoli, M - 555Zedda, A - 73Zeman, M - 173Zesch, J - 930Zettl, M - 692Zhang, B - 448Zhang, C - 823Zhang, H - 949Zhang, J - 267Zhang, L - 297, 311, 367, 556, 557, 964Zhang, M - 497, 642Zhang, S - 351Zhang, T - 554Zhang, W - 241, 483, 497, 642, 662, 800Zhang, X - 290, 369, 434, 979Zhang, Y - 149, 15, 162, 502, 732Zhang, Z - 377, 480, 714, 922Zhao, H - 723Zhao, L - 119, 198

Zhao, Y - 369, 979Zhao, Z - 760Zheng, X - 979Zheng, Z - 119Zhou, L - 714Zhou, T - 453, 758Zhu, J - 0, 117, 131, 177Zhu, L - 760, 770Zhu, M - 959Zhu, Q - 954Zhu, T - 729Zielke, D - 213Ziltener, R - 151Zimmer, M - 116Zimmermann, C - 421Zimmermann, K - 929Zin, N - 947Zinsser, B - 259, 574Znaidi, L - 471Zolla, H - 51Zubia, D - 309Zuschlag, A - 89, 90

Documents

PROGRAM 35th IEEE PHOTOVOLTAIC SPECIALISTS CONFERENCE