Chinese Materials Conference 2017 2017 China-Japan-Korea ... · Guanjun QIAO Jing SUN Xiaowei YIN Changan WANG Tae-Ho Kim Invited Invited Keynote Invited Invited Haijun ZHANG Kyung

Chinese Materials Conference 2017

2017

China-Japan-Korea

Multifunctional

Nanomaterials

Seminar

Program and Abstracts

July 6-9, 2017

Yinchuan, China

I

2017 China-Japan-Korea Multifunctional Nanomaterials Seminar

July 6-9, 2017 in Yinchuan, China

Venue: Ningxia, China

General Chair: Soo Wohn Lee

(President of IUMRS)

Yafang Han

(First Vice President of IUMRS)

Conference Chair: Yong Jiang

(University of Science and Technology Beijing, China)

Rongming Wang

(University of Science and Technology Beijing, China)

Hyeongtag Jeon

(Hanyang University, Korea)

Tohru Sekino

(Osaka University, Japan)

General secretary Wenbin CAO

(University of Science and Technology Beijing)

Secretary

Jianlei KUANG


Qi WANG


III

Table of Contents

Welcome Address

Organization Committee

General Information

Session List and Presentation Guide

Program Overview

Program

Abstract

• Plenary Lecture

• Keynote, Invited and Oral Presentation

• Poster and Published Only

Author Index

Acknowledgement

1

Welcoming Address

Dear Colleagues,

On behalf of the Organizing Committee of the 2017 China-Japan-Korea Multifunctional Nanomaterials

Seminar (2017CJK), it is our pleasure to extend a warm welcome to you. The China-Japan-Korea (CJK)

trilateral seminar was initiated by Prof. Soo Wohn Lee in 2005 in collaboration with Chinese, Japanese, and

Korean professors with expertise in nano-, environmental, energy-, and bio-materials. The annual CJK

seminars have since been organized in each of the three countries in turn. The 2017CJK will be held at

Yinchuan, China on July 6-9, 2017.

The topic of the present seminar is nanomaterials, which constitute an important branch in the

burgeoning field of nanoscience. Size reduction can lead to a whole range of new physicochemical

properties and a wealth of potential applications. However, the detailed understanding of nanomaterials

requires the development of suitable methods for their elaboration. China, Japan and Korea have made great

progress on nanomaterials in recent years, ranging from fundamental research to practical applications.

The 2017CJK aims to bring together leading experts and aspiring scientists from China, Japan and

Korea to present and discuss the latest progress on both fundamental studies and applied research in each

aspect of nanomaterials, advanced structural materials and functional materials. Information exchange and

research collaboration will be promoted through stimulating results, engaging discussion and flexible

interactions. All kinds of issues in terms of nano-technology, bio-technology, information technology,

environmental and energy technology on nanomaterials, advanced structural materials and functional

materials can be presented.

The following four topics and a young scientist (younger than 45) forum have been formed for the joint

seminar (the topics are not limited to these areas):

1. Basic principles and fundamental properties of multifunctional nanomaterials

2. The physical and chemical properties of nanoscale structures

3. The design methods and fabricating technology for nano-structures

4. The industrial and potential applications of nanomaterials

5. Young Scientists Forum on nanomaterials, advanced structural materials and functional materials

Looking forward to seeing all of you in Yinchuan, China, on 6-9 July 2017.

Sincerely yours,

Prof. Soo Wohn Lee, Yafang Han

General Chairs

2

Organizing Committee

General Chair:

Soo Wohn Lee, President of IUMRS

Yafang Han, First Vice President of IUMRS

Conference Chair

Yong Jiang, University of Science and Technology Beijing, China

Rongming Wang, University of Science and Technology Beijing, China

Hyeongtag Jeon, Hanyang University, Korea

Tohru Sekino, Osaka University, Japan

International Advisory Committee

Lei Jiang, Institute of Chemistry, Chinese Academy of Sciences, China

Feng PAN, Tsinghua University, China

Huai Yang, Peking University, China

Yanglong Hou, Peking University, China

Yongfa Zhu, Tsinghua University, China

Chen Gao, University of Science and Technology of China, China

Shaoxiong ZHOU, Advanced Technology & Materials Co. Ltd., China

Zhengyi FU, Wuhan University of Technology, China

Yuhua Wang, Lanzhou University, China

Xiaoyan Song, Beijing University of Technology

Junichi Hojo, Kyushu University, Japan

Shu YIN, Tohoku University, Japan


Hyeongtag Jeon, President of MRS-K, Hanyang University, Korea

Woo-Gwang Jung, Kookmin University, Korea

Jung-Sik Kim, University of Seoul, Korea

Bo Young Hur, GyeongSang National University, Korea

Ho Jung Chang, Dankook University, Korea

Academic Committee

Dongfeng Xue, Changchun Institute of Applied Chemistry, China

Xun Wang, Tsinghua University, China

Shuhong Yu, University of Science and Technology of China, China

Lin Guo, Beihang University, China

Liangti Qu, Beijing Institute of Technology, China

Yong Zhou, Nanjing University, China

Guanjun Qiao, Jiangsu University, China

Hao Wang, Wuhan University of Technology, China

Jing Sun, Shanghai Institute of Ceramics, CAS, China

Jianfeng YANG, Xi`an Jiatong University, China

3

Wenbin CAO, University of Science and Technology Beijing, China

Xuebin ZHENG, Shanghai Institute of Ceramics, CAS, China



Hiroshi Kageyama, Kyoto University, Japan

Katsuro Hayashi, Kyushu University, Japan

Kazuhiko Maeda, Tokyo Institute of Technology, Japan

Hikaru Ogino, Advanced Industrial Science and Technology (AIST), Japan

Tadachika Nakayama, Nagaoka Univ of Technology


Jae Hyun Kim, DGIST, Korea

Younghee Kim, KICET, Korea

Heon Lee, Korea University, Korea

Sang Sub Kim, Inha University, Korea

Geun-Young Yeom, Sungkyunkwan University, Korea

Taik Nam Kim, Paichai University, Korea

Jin Hyeok Kim, Chungnam National University, Korea

Do-Kyun Kwon, Korea Aerospace University, Korea

Do Kyung Kim, KAIST, Korea

Session Chairs

Session 1

Guanjun QIAO (Jiangsu University, Xi’an Jiaotong University, China)

Chunli LIU (Hankuk University, Korea)

Jae Hyun Kim (DGIST, Korea)

Liangti QU (Beijing Institute of Technology, China)

Session 2:

Bo Young HUR (Gyeongsang National University, Korea)

Huai YANG (Peking University, China)

Do-Kyun Kwon (Korea Aerospace University, Korea)

Yongfa ZHU (Tsinghua University, China)

Session 3:

Jianfeng YANG (Xi'an Jiaotong University, China)

Shu YIN (Tohoku University, Japan)

Chengbao JIANG (Beihang University, China)

Heon Lee (Korea University, Korea)

Session 4

Jung Sik Kim (University of Seoul, Korea)

Yanglong HOU (Peking University, China)

Yong ZHOU (Nanjing University, China)

Sang Sub Kim (Inha University, Korea)

4

Session 5:

Ze LIU (Wuhan University, China)

Tomoyo Goto (Osaka University, Japan)

Yu Horiuchi (Osaka Prefecture University, Japan)

Yan LI (University of Science and Technology Beijing, China)

Editors of proceedings

Wen-Bin Cao, University of Science and Technology Beijing, China

Yan Yu, University of Science and Technology China, China



5

General Information

Venue

Rieter Shenzhen Air International Hotel (银川立达深航国际酒店), Yinchuan (银川), Ningxia(宁夏), China

Schedule

08:30-12:30 14:00-17:30

July 6 09:00-21:00: Registration, 18:00: Buffet reception

July 7

Opening

Plenary

Parallel sessions

Parallel sessions

Poster session

Banquet

July 8 Plenary

Parallel sessions

Parallel sessions

Banquet

Registration

All the participants are asked to make the registration. The registration fee will cover the abstract books,

welcome party, all conference sessions, banquet. And the registered participants of this seminar will

automatically obtained their opportunities to attend the followed C-MRS 2017 conference (Jul 8-12) freely

without paying any further registration fees.

Registration Fee

On or before May 31th After May 31th

Regular participant 1600 RMB (250 USD) 1800 RMB (300 USD)

Students 1200 RMB (180 USD) 1300 RMB (200 USD)

Poster Award

To encourage more students to present their good research results, Best Student Posters will be awarded after

their presentation in poster session. Ten winners will be selected by a special committee. Each winner will

receive 600 RMB cash award and a Certificate with the signature of the President and the first Vice-president

of IUMRS at the Award Ceremony during the banquet. A student competing for best poster award must be

listed as the first author as well as the presenting author of a paper submitted for poster presentation.

Publication

Full paper submission: August 15, 2017, selected papers on nanomaterials will be published in a focus issue

of Nanotechnology (IOP) after peer review.

6

Contact

General secretary: Professor Wenbin CAO

University of Science and Technology Beijing

School of Materials Science and Engineering

Beijing 100083, China

Tel: + 86-10-6233-2457

Mobile phone: 86-13691526308

Fax: + 86-10-6233-2457

E-mail: [email protected]

Supporting Media

http://www.cailiaoren.com/

7

Session list and presentation guide

Session:

1. Basic principles and fundamental properties of multifunctional nanomaterials

2. The physical and chemical properties of nanoscale structures

3. The design methods and fabricating technology for nano-structure

4. The industrial and potential applications of nanomaterials

5. Young Scientists Forum on nanomaterials, advanced structural and functional materials

Oral Presentations:

Plenary lecture: 40 min, including 5 min for discussion, at large hall.

Keynote lecture: 30 min, including 5 min for discussion, at session room.

Invited lectures: 25 min, including 5 min for discussion, at session room.

General oral presentation: 20 min, including 5 min for discussion, at session room.

Please bring your own PC, the PC is not equipped with each room.

Poster Presentation:

The poster size should be within 120 cm length and 80 cm width. The poster number will be indicated on the

board.

The poster is requested to mount and remove as follows:

Mount: by 12:00 7 July.

Remove: by 18:00 7 July.

Any poster remaining after 18:00 will be removed and disposed by the secretariat.

8

Program Overview (Location: Rieter Shenzhen Air International Hotel 银川立达深航国际酒店)

Date Time

10:20-10:35

12:35-14:00

TimeSession 1:

Chair: Chunli LIU,Guanjun QIAO

Session 2:Chair: Bo Young HUR,

Huai YANG

Session 3:Chair: Jianfeng YANG,

Shu YIN

Session 4:Chair: Jung Sik Kim,

Yanglong HOU

Session 5:Chair: Ze LIU,Tomoyo Goto

Keynote Keynote Keynote Keynote Keynote

Ke XIA Huai YANG Yong JIANG Yanglong HOU Yan YU

Keynote Keynote Keynote Keynote Keynote

Xun WANG Bo Young HUR Xiaoyan SONG Yong ZHOU Yamato Hayashi

Keynote Keynote Keynote Keynote Invited

Guozhen SHEN Rongming WANG Shu YIN Wenbin CAO Zhongqi SHI

15:30-15:50


Guanjun QIAO Jing SUN Xiaowei YIN Changan WANG Tae-Ho Kim

Invited Invited Keynote Invited Invited

Haijun ZHANG Kyung Nam Kim Jianfeng YANG Yongqing WANG Yu Horiuchi

Invited Invited Oral Oral Oral

Chunli LIU Dae-Yong Jeong Zengchao YANG Sibin DUAN Wei WANG

Oral

Qinqin XU

Time

10:30-10:45

12:05-14:00

TimeSession 1:

Chair: Jae Hyun Kim,Liangti QU

Session 2:Chair: Do-Kyun

Kwon, Yongfa ZHU

Session 3:Chair: ChengbaoJIANG, Heon Lee

Session 4:Chair: Yong ZHOU,

Sang Sub Kim

Session 5:Chair: Yu Horiuchi,

Yan LIKeynote Keynote Keynote Keynote Keynote

Liangti QU Yongfa ZHU Chengbao JIANG Younghee Kim Ze LIU


Jae Hyun Kim Jin Hyeok Kim Heon Lee Sang Sub Kim Tomoyo Goto


Luning WANG Dongfeng XUE Chen GAO Jiangtao LI Yan LI

15:30-15:50


Lidong LI Hailei ZHAO Xuebin ZHENG Hao WANG (HUBU) Bo WANG

Invited Invited Invited Invited Oral

Hao WANG(WHUT) Do-Kyun Kwon Yuan DENG Chunxiang XU Cuixin CHEN

Oral

Rongfei XU

Oral

Lichao WANG

14:00-15:30

15:50-17:30

15:50-17:30

08:30-09:10

09:10-09:50

09:50-10:30

10:45-11:25

11:25-12:05

7 July

14:00-15:30

08:30-09:00

09:00-09:40

09:40-10:20

10:35-11:15

11:15-11:55

11:55-12:35

Lunch Break

8 July

International Hall

Coffee Break

Coffee Break

Lunch Break

Coffee Break

International Hall

Coffee Break

Soo Wohn Lee (President of IUMRS), Yafang Han (First Vice President of IUMRS)

Plenary

Shuhong YU (University of Science and Technology of China, China)

Plenary

Hyeongtag Jeon (Hanyang University, Korea)

Chair:Yong JIANG

Plenary

Masakazu ANPO (Osaka Prefecture University, Japan)

Plenary

Feng PAN (Tsinghua University, China)

Opening and Photo Session

Plenary

Guowen MENG (Institute of Solid State Physics, CAS, China)

Chair:Hyeongtag Jeon

Plenary

Lin GUO (Beihang University, China)

Plenary

Jung Sik Kim (University of Seoul, Korea)

Plenary

Tohru Sekino (Osaka University, Japan)

Chair:Rongming WANG

Plenary

Zhaoping LU (University of Science and Technology Beijing, China)

Plenary

Woo Gwang Jung (Kookmin University, Korea)

Chair:Tohru Sekino

9

Program (Location: Rieter Shenzhen Air International Hotel 银川立达深航国际酒店)

Plenary Session

July 7, International Hall (3rd Floor)

No. Time Name Affiliation Title

Chair: Yong Jiang (University of Science and Technology Beijing)

08:30-09:00 Soo Wohn Lee,

Yafang Han IUMRS Opening

FA-01 09:00-09:40 Shuhong YU

University of Science

and Technology of

China

Macroscopic Nanoparticle Assembles: Integration,

Functionalization and Applications

FA-02 09:40-10:20 Hyeongtag Jeon Hanyang University Multilayered SnS2 Materials for Thin Film Transistor

10:20-10:35 Coffee Break

Chair: Hyeongtag Jeon (Hanyang University)

FA-03 10:35-11:15 Masakazu

ANPO

Osaka Prefecture

University

Challenges in Efficient Sunlight Utilization for TiO2

Photocatalytic H2 Production from Water Involving

Biomass by Its Integration into an Artificial

Light-Type Plant Factory

FA-04 11:15-11:55 Feng PAN Tsinghua University Antiferromagnetic Metallic Materials and Spintronic

Devices

FA-05 11:55-12:35 Guowen Meng

Institute of Solid State

Physics, Chinese

Academy of Sciences

AAO-Template Assisted Synthesis of Hierarchically

Branched and Hybrid One-Dimensional

Nanoarchitectures for Devices

12:35-14:00 Lunch Break

July 8, International Hall (3rd Floor)

No. Time Name Affiliation Title

Chair: Rongming Wang (University of Science and Technology Beijing)

FA-06 08:30-09:10 Lin GUO Beihang University Nacre-Inspired Alumina Based Composites with

Exceptional Mechanical Properties

FA-07 09:10-09:50 Jung Sik Kim University of Seoul Sensitivity Improvement of the Micro Hydrogen

Sensor by Surface Modification

FA-08 09:50-10:30 Tohru Sekino Osaka University

Synthesis of Titania Nanotube and Nanostructure

Carbon Composites via Solution Chemical Routes

and Their Physical Properties


Chair: Tohru Sekino (Osaka University)

FA-09 10:45-11:25 Zhaoping LU University of Science

and Technology Beijing

Development of Next-Generation

High-Performance Metallic Materials via

Strengthening from Fully Coherent

Nano-Precipitates

FA-10 11:25-12:05 Woo Gwang

Jung Kookmin University

Fabrication of RGO Nanocomposite Materials

Based on Solution Process Platform and Their

Applications

12:05-14:00 Lunch Break

10

Keynote, Invited and Oral Sessions

[Session 1: Basic principles and fundamental properties of multifunctional nanomaterials]

July 7, Room 1 (3rd Floor)

No. Type Time Name Affiliation Title

Chair: Guanjun QIAO (Jiangsu University), Chunli LIU (Hankuk University)

FA-11 Keynote 14:00-14:30 Ke Xia Beijing Normal

University

Magnon-Phonon Interaction in YIG and

Effective Spin Mixing Conductance of

YIG-metal Interfaces

FA-12 Keynote 14:30-15:00 Xun WANG Tsinghua University Sub-1nm Ultrathin Nanocrystals

FA-13 Keynote 15:00-15:30 Guozhen SHEN

Institute of

Semiconductors,

Chinese Academy of

Sciences

Developing Low-Dimensional

Nanostructures for Flexible Sensors and

Integrated Systems


FA-14 Keynote 15:50-16:20 Guanjun QIAO Jiangsu University

Wetting and Interfacial Behavior of

Different Metals on WC-Co Cemented

Carbide

FA-47 Invited 16:20-16:45 Haijun Zhang

Wuhan University of

Science and

Technology

High Catalytic Activity for Aerobic

Glucose Oxidation of Colloidal Single

Atom Catalysts

FA-48 Invited 16:45-17:10 Chunli LIU Hankuk University of

Foreign Studies

Magnetically Separable Sulfur-Doped

SnFe2O4/Graphene Nanohybrids as for

Effective Visible Light Photocatalyst



Chair: Jae Hyun Kim (DGIST), Liangti QU (Beijing Institute of Technology)

FA-15 Keynote 14:00-14:30 Liangti QU Beijing Institute of

Technology

Graphene in Energy-Conversion and

-Storage System

FA-16 Keynote 14:30-15:00 Jae Hyun Kim DGIST Advanced Anode Materials for Li-Ion

Batteries (LTO, SiO)

FA-17 Keynote 15:00-15:30 Luning WANG


and Technology

Beijing

Recent Progress on Bioabsorbable Zinc

Alloys


FA-18 Keynote 15:50-16:20 Lidong LI


and Technology

Beijing

Tunable Metal-Enhanced Fluorescence

FA-49 Invited 16:20-16:45 Hao WANG Wuhan University of

Technology

Preparation, Microstructure and Properties

of MgAlON: Mn2+ Fluorescent

Transparent Ceramics

11

[Session 2: The physical and chemical properties of nanoscale structures]



Chair: Bo Young HUR (Gyeongsang National University), Huai YANG (Peking University)

FA-19 Keynote 14:00-14:30 Huai YANG Peking University Light Transmittance Adjustable Films

FA-20 Keynote 14:30-15:00 Bo Young HUR Gyeongsang National

University

Development of Functional Metallic

Materials of Molten Bubble Porous

Formation for Environmental Applications

FA-21 Keynote 15:00-15:30 Rongming

WANG


and Technology

Beijing

High Density Single Atom Catalysts:

Synthesis and Catalytic Performances

towards CO Oxidation


FA-22 Keynote 15:50-16:20 Jing SUN Shanghai Institute of

Ceramics, CAS

Synthesis of Metal Nanowires and Their

Application as Stretchable Conductive

Fibers

FA-50 Invited 16:20-16:45 Kyung Nam

Kim Kangwon University

Synthesis and Photoluminescence

Properties of Metal Oxide Nanomaterials

for Scintillator

FA-51 Invited 16:45-17:10 Dae-Yong

Jeong Inha University

Fabrication and Ferroelectric Properties of

Artificial Nano-Composite with

Nano-Clustering Methods



Chair: Do-Kyun Kwon (Korea Aerospace University), Yongfa ZHU (Tsinghua University)

FA-23 Keynote 14:00-14:30 Yongfa ZHU Tsinghua University Supramolecular Organic Photocatalysts

with High Visible Light Performances

FA-24 Keynote 14:30-15:00 Jin Hyeok Kim Chonnam National

University

Utilization of Wide-band Gap TCO

Windows in Cu2ZnSn(S, Se)4 Thin Film

Solar Cells

FA-25 Keynote 15:00-15:30 Dongfeng XUE

Changchun Institute of

Applied Chemistry,

Chinese Academy of

Sciences

Crystallization of Rare Earth Functional

Materials


FA-26 Keynote 15:50-16:20 Hailei ZHAO


and Technology

Beijing

High Performance Anode Materials: In

Situ Exsolved Nanoparticle Catalysts

Decorated Ceramics

FA-52 Invited 16:20-16:45 Do-Kyun Kwon Korea Aerospace

University

Novel Dielectric Composite Films

Incorporated with Two-Dimensional Oxide

Nanosheet Fillers

12

[Session 3: The design methods and fabricating technology for nano-structure]



Chair: Jianfeng YANG (Xi'an Jiaotong University), Shu YIN (Tohoku University)

FA-27 Keynote 14:00-14:30 Yong JIANG


and Technology

Beijing

Spin Transport in Mn1.5Ga/Heavy Metal

Multilayers

FA-28 Keynote 14:30-15:00 Xiaoyan SONG Beijing University of

Technology

Stability of Nanocrystalline Metastable

Phases in Sm-Co Alloys

FA-29 Keynote 15:00-15:30 Shu YIN Tohoku University

Synthesis and Gas Sensing Properties of

Oxide Nanoparticles with Different

Morphologies


FA-30 Keynote 15:50-16:20 Xiaowei YIN

Northwestern

Polytechnical

University

Multi-Functional Si-C-N Ceramics

Fabricated by 3D Printing

FA-31 Keynote 16:20-16:50 Jianfeng YANG Xi'an Jiaotong

University

Study on the Frication and Application of

Porous Mullites with Whisker Framework

FA-62 Oral 16:50-17:10 Zengchao

YANG

Technical Institute of

Physics and Chemistry,

Chinese Academy of

Sciences

Combustion Synthesis of TiC/Al

Composite Materials under High Gravity



Chair: Chengbao JIANG (Beihang University), Heon Lee (Korea University)

FA-32 Keynote 14:00-14:30 Chengbao

JIANG Beihang University

Heterogeneous Magnetostriction in

Fe-Based Alloys

FA-33 Keynote 14:30-15:00 Heon Lee Korea University 3D Structured Photo-Electrode for

Efficient Solar Water Splitting

FA-34 Keynote 15:00-15:30 Chen GAO


and Technology of

China

Drifts Evidence for Facet-Dependent

Adsorption of Gaseous Toluene on TiO2

with Relative Photocatalytic Properties


FA-35 Keynote 15:50-16:20 Xuebin ZHENG

Shanghai Institute of

Ceramics, Chinese

Academy of Sciences

Cerium Oxide Based Coatings for

Osteoporotic Bone Regeneration

FA-53 Invited 16:20-16:45 Yuan DENG Beihang University

Concentrated Solar Generator and Sensor

Based on Flexible Thin Film

Thermoelectric Device

13

[Session 4: The industrial and potential applications of nanomaterials]



Chair: Jung Sik Kim (University of Seoul), Yanglong HOU (Peking University)

FA-36 Keynote 14:00-14:30 Yanglong HOU Peking University Phase-Controlled Synthesis and Potential

Application of Iron Carbide Nanoparticles

FA-37 Keynote 14:30-15:00 Yong ZHOU Nanjing University

Artificial Photosynthesis: Photocatalytic

Conversion of CO2 into Hydrocarbon

Fuelstitle

FA-38 Keynote 15:00-15:30 Wenbin CAO


and Technology

Beijing

Large-Scale Synthesis of Nitrogen Doped

TiO2 and Its Applications in Environment

Purification


FA-39 Keynote 15:50-16:20 Changan

WANG Tsinghua University

In-Situ Preparation of Binder-Free Nano

Cotton-Like CuO-Cu Integrative Anode on

Cu Current Collector by Laser Ablation for

Li-Ion Battery

FA-54 Invited 16:20-16:45 Yongqing Wang Sun Yat-sen University

Synthesis of TiO2-Based Core-Shell

Structure and Its Application in

Photocatalysis

FA-63 Oral 16:45-17:05 Sibin DUAN


and Technology

Beijing

Pt1/Fe2O3 Single-Atom Catalyst with High

Number Density



Chair: Yong ZHOU (Nanjing University), Sang Sub Kim (Inha University)

FA-40 Keynote 14:00-14:30 Younghee Kim

Korea Institute of

Ceramic Engineering

and Technology

SiC Powder for Semi Insulating SiC Single

Crystal Growth

FA-41 Keynote 14:30-15:00 Sang Sub Kim Inha University

Development of Chemiresistive Gas

Sensors Based on Oxide Nanomaterials for

Environmental Monitoring

FA-42 Keynote 15:00-15:30 Jiangtao LI

Technical Institute of

Physics and Chemistry,

CAS

High-Entropy Alloys Prepared by

High-Gravity Combustion Synthesis and

Their Cryogenic Properties


FA-43 Keynote 15:50-16:20 Hao Wang Hubei University One-Dimensional Metal Oxide Nanoarrays

for Optoelectronic Devices

FA-55 Invited 16:20-16:45 Chunxiang XU Southeast University Plasmon-Enhanced ZnO WGM Lasing and

Single-Mode Realization

14

[Session 5: Young Scientists Forum on nanomaterials, advanced structural and functional materials]



Chair: Ze LIU (Wuhan University), Tomoyo Goto (Osaka University)

FA-44 Keynote 14:00-14:30 Yan YU


and Technology of

China

Advanced Sodium-Ion Batteries Based on

NASICON-Type Materials

FA-45 Keynote 14:30-15:00 Yamato Hayashi Tohoku University

Fabrication and Characterization of Silver

Nanowire Transparent Conductive Film by

Needle Shaped Organic Precursor Painting

Reduction System

FA-56 Invited 15:00-15:25 Zhongqi Shi Xi’an Jiaotong

University

Morphological-Controlled Combustion

Synthesis of Aluminum Nitride Powders

and Their Application


FA-57 Invited 15:45-16:10 Tae-Ho Kim Sun Moon University

Synthesis of Morphology Controllable

High Activity Solar-Light-Driven

Photocatalyst for Environmental

Applications

FA-58 Invited 16:10-16:35 Yu Horiuchi Osaka Prefecture

University

Metal-Containing Nitrogen-Doped

Nanoporous Carbons Derived from Metal

Organic Frameworks Designed for

Catalytic and Electrocatalytic Applications

FA-64 Oral 16:35-16:55 Wei WANG Chang’an University

Preparation of Mullite Whiskers on

Cordierite Diesel Particulate Filters

through In-Situ Molten Salt Reactions

FA-65 Oral 16:55-17:15 Qinqin XU Guizhou University

An Electrochemical and SERS Study of

CO Oxidation on Core-Shell Au@Rh

Nanoparticle Electrodes



Chair: Yan LI (University of Science and Technology Beijing), Yu Horiuchi (Osaka Prefecture University)

FA-46 Keynote 14:00-14:30 Ze LIU Wuhan University

One-Step Fabrication of Crystalline Metal

Nanostructures by Direct Nanoimprinting

below Melting Temperatures

FA-59 Invited 14:30-14:55 Tomoyo Goto Osaka University

Adsorption Behavior of Acidic Dye on

TiO2-Modified Hydroxyapatite as

Photocatalyst

FA-60 Invited 14:55-15:20 Yan LI


and Technology

Beijing

Hydroxylation of Graphene Quantum Dots

and Its Application to Sensitive Detect of

Cr3+ Ions

15


FA-61 Invited 15:40-16:05 Bo Wang

Xi'an Jiaotong

University

High Strength Porous SiC Ceramics

Fabricated by Vapor-Solid Reaction and

Subsequent Recrystallization Sintering

FA-66 Oral 16:05-16:25 Cuixin CHEN Hebei University of

Technology

Nano Inoculant Preparation and Its

Refinement Effect on Microstructure of

Nickel Based Alloy Weld

FA-67 Oral 16:25-16:45 Rongfei XU China University of

Petroleum

Metal Organic Framework Derived CoS

Hollow Sphere: Fabrication and Their

Application in Lithium-Sulfur Batteries

FA-68 Oral 16:45-17:05 Lichao WANG Donghua University

Au/Hydrogen-Treated 3DOM-WO3

Catalyst for Reduction of CO2 to Fuels

(CH4 and CH3OH) with Enhanced

Photo-Thermal Catalytic Performances

and DFT Study

16

Poster

No. Name Affiliation Title

FA-P01 Yanhua Jia Jiangxi Science and Technology

Normal University

Effects of Organic Additives and

Post-Treatment on Electrical Conductivity and

Thermopower of PEDOT via VPP

FA-P02 Dening Zou Xian University of Architecture and

Technology

Effect of Nano-Scale Cu-rich Precipitated

Phase on Mechanical Properties of Precipitation

Hardening Stainless Steel

FA-P03 Wenfang Wang Jiangxi Science and Technology

Normal University

Fabrication of Freestanding Te Nanofilm and

Its Thermoelectric Performance

FA-P04 Xia Li Jiangxi Science and Technology

Normal University

Thermoelectric Performance of PEDOT:

PSS/MoSe2 Composite

FA-P05 Qiang Wu Shihezi University

Impacts of Reduced Graphene Oxide as the

Surface-Modification Layer in CdS/CdSe

Quantum Dots Co-Sensitized Solar Cells

FA-P06 Tongzhou Wang Jiangxi Science and Technology

Normal University

Thermoelectric Performance of PEDOT:

PSS/WS2 Composite Thin Film

FA-P07 Changcun Li Jiangxi Science and Technology

Normal University

Fabrication of Flexible SWCNTs-Te Composite

Films for Improving Thermoelectric Properties

FA-P08 Guangya Hou Zhejiang University of Technology

High Catalytic Activity for Methanol

Electrooxidation of Ni-Cu-B

Nanoparticles/TiO2 Nanotube Arrays

Composite Electrode

FA-P09 Xiaodong Wang Jiangxi Science and Technology

Normal University

An Effective Dual-Solvent Treatment for

Improving Thermoelectric Property of PEDOT:

PSS with White Graphene

FA-P10 Jing Feng Changjiang River Scientific Research

Institute

Preparation and Durability of Fluorocarbon

Nanocomposite Coatings on Hydraulic Cement

Substrates

FA-P11 Jin Han Zhejiang University of Technology Skinning of High Thiol Content Polythiols on

Copper to Inhibit Corrosion

FA-P12 Jie Fei Shanxi University of Science and

Technology

Grafting Aligned ZnO Nanorods onto Carbon

Fabric for Superior Tribological Performance

FA-P13 Jiahui Li Donghua University

High Performance All-Solid-State Asymmetric

Wearable Supercapacitor Based on Hybrid

Fibers Made of Liquid Exfoliated Molybdenum

Disulfide and Reduced Graphene Oxide

FA-P14 Hongwei Li Chang'an University

Introduction of Nano Silica into Silica Sol：

Strengthening Aerogel and Dispersing Glass

Fiber

FA-P15 Xuejing Li Jiangxi Science and Technology

Normal University

Preparation of Highly Conductive PEDOT: PSS

Film and Its Wetting-Transfer

17

FA-P16 Qi Guo University of Science and Technology

Beijing

In-Plane Electric Field Controlled Magnetism

in an La2/3Sr1/3MnO3/

[Pb(Mg1/3Nb2/3)O3]0.7-(PbTiO3)0.3

Heterostructure

FA-P17 Yanling Yang University of Science and Technology

Beijing

Shot Noise and Electronic Properties in the

Inversion Symmetric Weyl Semimetal Resonant

Structure

FA-P18 Jinfen Niu Xi’an University of Technology

A Facile Microwave Hydrothermal Route for

Trinary γ-Fe2O3@TiO2/GR Hybrids as a

Visible-Light-Driven Photocatalyst

FA-P19 Quantong Yao Northeastern University

The Research on Nanocrystalline Layer

Produced by Means of Industrialized

Mechanical Shot Blasting

FA-P20 Yan Li Iron and Steel Research Institutes of

Ansteel Group Corporation

Research on the lubrication performance and

mechanisms of Nano-BN in Water-based

Rolling Liquid

FA-P21 Jianlei Kuang University of Science and Technology

Beijing

Enhanced Dielectrical Permittivity and

Microwave Absorption of SiC Nanowires

FA-P22 Chuan Huang Institute of Chemical Materials, China

Academy of Engineering Physics

Tuning Reactivity of Nanoaluminum with

Fluoropolymer via Electrospray Deposition

FA-P23 Wen-Xiu LIU University of Science and Technology

Beijing

SnO Hierarchical Architectures with Different

Sizes: One-Step Synthesis, Formation

Mechanism, and Photocatalytic Properties

FA-P24 Guodong Zhang Wuhan University Self-Propagating High-Temperature Synthesis

of Spherical Alumina Nanoparticles

FA-P25 Xiaolin Qiu Jiangnan University

Development and Properties of Active

Packaging Films Containing Antioxidant

Loaded with Mesoporous Molecular Sieve

FA-P26 Jing Zhao

Shenzhen Institutes of Advanced

Technology, Chinese Academy of

Sciences

Synthesis of MIL88A MOF for Efficiently and

Safe Gene Delivery in Vivo

FA-P27 Rui Zhang University of Science and Technology

Beijing

Facile Synthesis of SnO/TiO2 Heterojunction

Photocatalysts with Enhanced Photocatalytic

Activity

FA-P28 Yi-Yao Ge Tsinghua University Synthesis of Er3+-doped Perovskite NaNbO3

Nanorods with UC PL Behavior

FA-P29 Sheng-nian TIE Qinghai University

Influence on Remove Carbon Effect of

Micro-Nano Silica Fume by Current

Classification

FA-P30 Yuncheng Zhou University of Science and Technology,

Beijing

Rapid Microwave Assisted Synthesis of

YIn1-xMnxO3 Blue Pigments: Synthesis,

Microstructure and Optical Properties

18

FA-P31 Lichao Wang Donghua University

AuPd/3DOM-WO3 Catalyst for Photo-thermal

Catalytic Reduction of CO2 to Fuels with

Enhanced Catalytic Performances and DFT

Study

FA-P32 Zhaoying Guo University of Science and Technology

Beijing

Synthesis and Photocatalytic Property of

Urchin-like Titania Microspheres

FA-P33 Dejun Zeng Xi’an Jiaotong University

Fabrication and Properties of Ceramic/ Epoxy

Composites by Infiltrating Epoxy into Mullite

Whisker Frameworks

19

Abstracts

Plenary Lecture

20

FA-01 09:00-09:40, July 7, International Hall (3rd Floor) Plenary

Macroscopic Nanoparticle Assembles: Integration, Functionalization and

Applications

Shu-Hong Yu*

Division of Nanomaterials and Chemistry, Hefei National Laboratory for Physical

Sciences at Microscale, Department of Chemistry, CAS Center for Excellence in

Nanoscience, University of Science and Technology of China, Hefei, China, 230026

The huge diversity of hierarchical micro-/nano-rigid structures existing in biological systems is increasingly

becoming a source of inspiration of materials scientists and engineers to create next generation advanced

functional materials. Recently, accompanied with the development of nanotechnology, some biologically

hierarchical rigid structures have been duplicated and mimicked in artificial materials through hierarchical

organization of micro-/nanosized building blocks. Although the properties of nanomaterials are frequently

superior to those of their bulk counterparts, translating the unique characteristics of individual nanoscale

components into macroscopic functional devices still remains a challenge.

In this lecture, we discuss how to assemble nanoscale building blocks into ordered assemblies as well as

their functionalities, and how to integrate them with already existing macroscopic structures and realize their

functionalization. A family of nanowire or nanoplate assemblies in form of thin films or 3D integrated structures

can be generated, demonstrating that it is possible to access a variety of high quality hybrid materials with tunable

mechanical property and other multifunctionalities. These assembled structures show enormous application

potential in diverse fields such as electronics, elastomeric conductors, electrocatalysis, and super adsorbents.

References

[1] L. B. Mao, H. L. Gao, H. B. Yao, L. Liu, H. Cölfen, G. Liu, S. M. Chen, S. K. Li, Y. X. Yan, Y. Y. Liu, S. H.

Yu, Science 2016, 345, 107-110.

[2] S. H. Yu, H. Cölfen, K. Tauer, M. Antonietti, Nat. Mater. 2005, 4, 51-55.

[3] Y. Yang, K. Wang, H. W. Liang, G. Q. Liu, M. Feng, L. Xu, J. W. Liu, J. L. Wang, S. H. Yu, Sci. Adv. 2015,

1, e1500714.

[4] H. L. Gao, Y. B. Zhu, L. B. Mao, F. C. Wang, X. S. Luo, Y. Y. Liu, Y. Lu, Z. Pan, Jin Ge, L. Xu, W. Shen,

W. H. Xu, L. J. Wang, H. A. Wu, S. H. Yu, Nat. Commun. 2016, 7, 12920.

[5] H. B. Yao, J. Ge, L. B. Mao, Y. X. Yan, S. H. Yu, Adv. Mater. 2014, 26, 163-188.

[6] H. B. Yao, H. Y. Fang, X. H. Wang, S. H. Yu, Chem. Soc. Rev. 2011, 40, 3764-3785.

[7] Z. Y. Wu, H. W. Liang, L. F. Chen, B. C. Hu, S. H. Yu, Acc. Chem. Res. 2016, 49, 96-105.

[8] H. W. Liang, J. W. Liu, H. S. Qian, S. H. Yu, Acc. Chem. Res. 2013, 46, 1450-1461.

[9] J. W. Liu, H. W. Liang, S. H. Yu, Chem. Rev. 2012, 112, 4770-4799.

[10] H. W. Liang, Q. F. Guan, L. F. Chen, Z. Zhu, W. J. Zhang, S. H. Yu, Angew. Chem. Int. Ed. 2012, 51,

5101-5105.

[11] J. W. Liu, J. H. Zhu, C. L. Zhang, H. W. Liang, S. H. Yu, J. Am. Chem. Soc. 2010, 132, 8945-8952.

21

CV

Name: Shu-Hong Yu Nationality: Chinese

Affiliation: University of Science and Technology of China Position: Professor

Telephone: +86 551 63603040 Facsimile: +86 551 63603040


Mail address: Department of Chemistry, University of Science and Technology of China,

Hefei 230026, P. R. China.

Education

Shu-Hong Yu studied chemistry in Hefei University of Technology and received BS in 1988. He got MS from

Shanghai Research Institute of Chemical Industry (SRICI) in 1991. He completed PhD in Inorganic Chemistry in

1998 from University of Science and Technology of China (USTC).

Working Experience

From 1999 to 2001, he worked in Materials and Structures Laboratory, Tokyo Institute of Technology (TIT), as a

Research Postdoctoral Fellow, working with Prof. Masahiro Yoshimura. He was awarded the AvH (Alexander von

Humboldt Foundation) Fellowship (2001-2002) in the Max Planck Institute of Colloids and Interfaces, Germany,

working with Prof. Dr. Markus Antonietti and Prof. Dr. Helmut Cölfen. He was appointed as a full professor in

2002 and the Cheung Kong Professorship in 2006 by the Ministry of Education in the Department of Chemistry,

University of Science and Technology of China (USTC). He is a Fellow of the Royal Society of Chemistry

(2013-), is acting as a General Secretary and a Council member of the International Solvothermal Hydrothermal

Association (ISHA) (2010-). Currently, he is leading the Division of Nanomaterials & Chemistry, Hefei National

Laboratory for Physical Sciences at Microscale (HFNL), USTC. He was appointed as Group Leader of the

Partner Group of the Max Planck Society and the Chinese Academy of Sciences, USTC, from 2005 to 2009.

Five main Scientific Publications

1. Li-Bo Mao, Huai-Ling Gao, Hong-Bin Yao, Lei Liu, Helmut Cölfen, Gang Liu, Si-Ming Chen, Shi-Kuo Li,

You-Xian Yan, Yang-Yi Liu, Shu-Hong Yu*, Synthetic nacre by predesigned matrix-directed mineralization,

Science 2016, 354, 107-110.

2. Huai-Ling Gao†, Yin-Bo Zhu†, Li-Bo Mao, Feng-Chao Wang, Xi-Sheng Luo, Yang-Yi Liu, Yang Lu, Zhao

Pan, Jin Ge, Liang Xu, Wei Shen, Wei-Hong Xu, Lin-Jun Wang, Heng-An Wu*, and Shu-Hong Yu*,

Super-Elastic and Fatigue Resistant Carbon Material with Lamellar Multi-Arch Microstructure, Nat.

Commun. 2016, 7, 12920.

3. Yuan Yang, Kai Wang, Hai-Wei Liang, Guo-Qiang Liu, Mei Feng, Liang Xu, Jian-Wei Liu, Jin-Long Wang,

Shu-Hong Yu*, A new generation of alloyed/multimetal chalcogenide nanowires by chemical transformation,

Sci. Adv. 2015, 1, e1500714.

4. Min-Rui Gao†, Jin-Xia Liang†, Ya-Rong Zheng, Yun-Fei Xu, Jun Jiang, Qiang Gao, Jun Li and Shu-Hong

Yu*, An efficient molybdenum disulfide/cobalt diselenide hybrid catalyst for electrochemical hydrogen

generation, Nat. Commun. 2015, 6, 5982.

5. Shu-Hong Yu*, Helmut Cölfen*, Klaus Tauer, Markus Antonietti*, “Tectonic arrangement of BaCO3

nanocrystals into helices induced by a racemic block copolymer”, Nature Materials 2005, 4(1), 51-55.

22


Multilayered SnS2 Materials for Thin Film Transistor

Hyeongtag Jeon

Division of Materials Science and Engineering, Hanyang University, Seoul, Korea

Recently two-dimensional materials such as graphene, molybdenum disulfide (MoS2) and tungsten disulfide

(WS2) has been studied extensively due to their unique material properties applicable to the new nano scale

electronic devices. In particular, graphene and 2D-MoS2 are the most actively researched to exploit their unique

characteristics such as high transmittance, high carrier mobility, flexibility, and large specific surface area.

However, graphene has a zero bandgap in pristine form without functionalization or structural modification like a

ribbon shape, resulting in poor transistor performance. In order to find new materials with band gap, metal

dichalcogenides have been actively researched as a replacement of graphene. Transition metal dichalcogenides

(TDMCs) have been investigated to apply in the electronic devices due to their suitable bandgap, high carrier

mobility, flexibility and so on. TMDCs are generally formed by simple processing methods such as a mechanical

exfoliation, and chemical vapor deposition (CVD).

In this study, we deposited few-layers of SnS2 using Tetrakis (dimethylamino) tin and hydrogen sulfide at

very low temperature of 150°C with atomic layer deposition (ALD) method. And then, we annealed SnS2 with

various annealing temperatures to improve crystallinity of 2D SnS2. The properties of annealed and as-deposited

SnS2 were analyzed by XRD, RAMAN, TEM and XPS. And the transistors using few layers of SnS2 were

fabricated and their electrical properties were investigated.

CV

Name: Hyeongtag Jeon Nationality: Korea

Affiliation: Hanyang University Position: Professor

Telephone: +82-2-2220-0387 Facsimile: +82-2-2292-3523


Mail address: Division of Materials Science and Engineering Hanyang Univeristy 222 Wangsimni-ro,

Seongdong gu Seoul, 04763, Korea(South)

Education

1978-1982: B.S.: Metallurgical Engineering in Hanyang University, Korea

1982-1984: M.S.: Metallurgical Engineering in Hanyang University, Korea

1986-1990: Ph.D.: Materials Science and Engineering in North Carolina State University

Working Experience

1991: Senior Engineer at Hyundai Electronics

1992-Present: Professor at Hanyang University

2017: President of Materials Research Society of Korea

23


1. H. Jeon, J.G. Park, H.Y. Jeon, H.J. Kim, W.C. Jang, H.S. Song, H.G. Kim K.Y. Lee, RSC ADVANCES

5, p.68900-68905 (2015)

2. H. Jeon, T.H. Kang, J.Y. Rhie, J.H. Park, Y.M. Bahk, J.S. Ahn, D.S. Kim, Applied Physics Express 8,

p.092003-1~4 (2015)

3. H. Jeon, D.S. Han, J.H. Park, M.S. Kang, J.W. Park, JOURNAL OF NANOSCIENCE AND

NANOTECHNOLOGY 15, p.7606-7610 (2015)

4. H. Jeon, H.Y. Choi, S.Y. Shin, Y.T. Choi, J.H. Kim, S.H. Kim, S.C. Chung, K.Y. Oh, JOURNAL OF

VACUUM SCIENCE & TECHNOLOGY A 34, p.01A121-1~7 (2016)

5. H. Jeon, J.H. Oh, S.Y. Shin, J.H. Park, G.Y. Ham, Thin Solid Films 599, p.119-124 (2016)

24


Challenges in Efficient Sunlight Utilization for TiO2 Photocatalytic H2

Production from Water Involving Biomass by Its Integration into an

Artificial Light-Type Plant Factory

Masakazu ANPO*

Osaka Prefecture University, Emeritus Professor

(ex-Vice President, Advisor to President, Director of R&D Center for the Plant

Factory)

Fuzhou University, International Advisor of the State Key Laboratory

“Photocatalysis on Energy and Environment” & International College

Environmentally harmonious, clean and safe scientific technologies to address energy needs as well as

pollution and climatic change are the subject of much recent research. The development of photocatalytic

processes will advance sustainable, non-hazardous and economic technologies. We have successfully developed

Ti-oxide photocatalysts which enable the absorption of visible light to operate as an efficient

environmentally-friendly photocatalyst. This presentation will focus on efficient H2 production from H2O

involving biomass using visible light-responsive TiO2 thin film photocatalysts for the separate evolution of H2

and CO2 under sunlight irradiation.[1-4]

Research into the development of an artificial-light type plant factory to cultivate various vegetables will

also be introduced. These vegetables are grown within a shorter production time than in outdoor fields with

artificial LED lights in completely closed cleanrooms under high concentrations of CO2. The plant factory is a

new concept in agriculture to supply safe, nutritious produce year-round regardless of any adverse or disruptive

natural or manmade influences such as global warming, climate change, pollution or other potentially damaging

circumstances.

TiO2 photocatalytic H2 and CO2 production from H2O involving biomass as a sacrificial reagent will be

discussed by its integration into an artificial light-type plant factory as a clean, carbon-neutral and sustainable

chemical system in the effective utilization of sunlight.

25

Reference

[1] M. Anpo and P. V. Kamat, “Environmentally Benign Photocatalysts -Applications of Titanium Oxide-based

Materials”, Springer, USA, (2011), and references therein.

[2] M. Anpo, J. CO2 Utilization, 1, 8 (2013), and references therein.

[3] Y. Horiuchi, M.Takeuchi, M. Matsuoka, M. Anpo, Phys. Chem. Chem. Phys., 15, 13243 (2013).

[4] J. Schneider, M. Anpo, D. Bahnemann, et al., Chem. Rev., 114, 9919 (2014), and references therein.

[5] 安保、福田、和田；電気評論 2015年増刊号、7月 12-17頁。

CV

Name: Masakazu ANPO Nationality: Japan

Affiliation: Emeritus Professor, Osaka Prefecture University (Japan), International Advisor of the State Key

Laboratory of Photocatalysis on Energy and Environment, Fuzhou University (China)

Position: Professor

Telephone: -81-72-463-6016 Facsimile: -81-72-463-6016

E-mail: [email protected] or [email protected]

Employment

1975 - Research Assoc., Osaka Prefecture University, and Assist. Prof., then Assoc. Professor

1990 - Full Professor, Osaka Prefecture University

2007 - Dean, Graduate School of Engineering, Osaka Prefecture University

2009 - Vice-President and Executive Director, Osaka Prefecture University

2013 - Advisor to President (2015 March; Retirement)

2015 - Dean of International College of Fuzhou University (China)

2016 - International Advisor, State Key Laboratory of Photocatalysis on Energy and Environment Fuzhou

University (China)

Invited Professorships: (Total of 36 invited Professorship at universities and institutes.)

National Research Council Canada (Dr. K. U. Ingold) (1981, for 1 year)

Univ. of Pierre and Marie Curie in Paris (Univ. of Paris 6th); Tokyo Institute of Technology (1988); Nagoya

University (1995); Torino University (1994; Tokyo University (2000);

East China University of Science and Technology, Shanghai, China (2004-);

Fuzhou University (2004); Kyusyu University (2005); Osaka University (2006); etc.

Awards (8 awards) and Honor (3 big honors):

Award of the Japan Photochemical Society (1994); Award of the Chemical Society of Japan (2003);

Award of the Ministry of Education of Japan (2009); Award of the Catalysis Society of Japan (2011).

Member, Academia Europaea (2008); Member, Science Council of Japan (2011)

Fujian Provincial Hundred Foreign Experts (2015).

Plenary and Invited Lectures at the International Conferences: (Over 127 invited lectures)

Over 898 publications: Original papers: 533, Books: 114, Reviews: 149, Proceedings: 102

Editorships: Editor-in-Chief: [Research on Chemical Intermediates], Springer Publishers

26

Brief biography of Prof. Masakazu ANPO:

Prof. M. ANPO is presently the International Advisor of the State Key Laboratory of Photocatalysis on

Energy and Environment, Fuzhou University in China after retirement of Osaka Prefecture University (end of

March in 2015) where he worked for 40 years and served as Dean of Graduate School of Engineering (Faculty of

Engineering), Vice President and Executive Director, the Director of the R&D Center for Plant Factory, etc. and

Advisor to President for last 10 years. He is a pioneer in the research of photochemical reactions on solid surfaces

including catalysts and has published the first book in this field, “Photocatalysis” in 1988 from Asakura-shoten.

An English book, “Photochemistry on Solid Surfaces” was published in 1989 from Elsevier. Until today, he has

published more than 110 scientific books in English. Dr. Anpo has published over 533 original papers, being

cited more than 32,500 times. His dream is the establishment of “Solar Chemistry” as a new

environmentally-friendly science and technology. Especially, he has an interest in the hybridization of artificial

photosynthesis (photocatalysis) and natural photosynthesis. The hybridization of a visible light-responsive TiO2

thin film photocatalyst and natural photosynthesis of green plants in artificial light (LED)-type plant factory leads

to an efficient H2 production from water involving biomasses as well as a rapid production of clean and safe

vegetables by effective utilization of sunlight energy.

27


Antiferromagnetic Metallic Materials and Spintronic Devices

Feng Pan1*, Yuyan Wang2, Xiangjun Zhou1, and Cheng Song1

1Tsinghua University, Key Laboratory of Advanced Materials (MOE), School of

Materials Science and Engineering, Beijing, 100084, China

2Department of Physics, Beihang University, Beijing10091.

With the development of information technology, spintronic devices with high storage density, low power

consumption, and high write/read speed are strongly expected. The rigidity to external magnetic fields, the

absence of stray fields and theoretically predicted strong spin transfer torque capability make antiferromagnetic

(AFM) metals, compared to their ferromagnetic counterpart, particularly favorable for information storage

technology. How to manipulate the AFM moments in an effective way is a key issue in the practical application of

AFM spintronics. This paper proposes the main idea of manipulating the AFM properties by magnetic field,

ferromagnets and electric field. The magnetic mechanism of modulating AFM metals is mainly discussed.

Through designing the multilayers and device structures, AFM-based tunnel junctions and Hall devices were

developed to explore the application of AFM as functional materials in information technology.

Co/Pt ferromagnets with perpendicular magnetic anisotropy and IrMn AFM were adopted to design and

fabricate the AFM-based [Co/Pt]/IrMn/AlOx/Pt tunnel junctions, where room-temperature tunneling anisotropic

magnetoresistance (TAMR) effect is primarily realized. Driven by the magnetic reversal of Co/Pt moments, a

partial rotation of AFM moments in IrMn is observed. The results verify that the room-temperature TAMR in is

due to two crucial aspects: stable antiferromagnetic exchange spring in relatively thick IrMn (e.g., 6 nm) and

superior thermal tolerance of perpendicular exchange coupling. Element specific soft-x-ray absorption spectra are

further used to clarify and compare the exchange spring in FeMn and IrMn AFM, not only confirming the partial

rotation of AFM moments in tunnel junctions, but also clarifying the key issue on the relationship between

magnetoresistance and the exchange spring structure in AFM.

In order to achieve the independent manipulation of the two AFM electrodes in the tunnul junction, a novel

perpendicular bi-AFM-based junction with the core structure IrMn/AlOx/IrMn is designed. Co/Pt multilayers

with different perpendicular magnetic anisotropy are chosen as supporting materials to trigger different alignment

of the top and bottom IrMn moments, thus obtaining the room-temperature magnetoresistance effect with stable

high/low resistance states. This experimental observation clarifies the origin of the magnetoresistance which is

based on the interaction of the two AFM layers, and is practically significant that may pave the way for

new-generation AFM-based spintronics.

Field-direction dependence of anomalous Hall Effect, planar Hall Effect, and anisotropic magnetoresistance

have been systematically investigated in a perpendicularly exchange-coupled [Co/Pt]/IrMn system, clarifying the

reversal procedure of magnetic moments. It sheds promising light on a sensor for the detection of magnetic fields

in all the directions. The ionic liquid is further adopted as the dielectric gate to generate a large electric field by

forming an electric double layer, which primarily enables the modulation of the exchange spring in IrMn with the

thickness up to 5 nm, as well as exchange bias effect. The electrical control of spin behaviors in AFM metals

would provide an attractive alternative towards practical AFM spintronics.

28

References

[1] Wang Y Y, Song C, Cui B, Wang G Y, Zeng F, Pan F. Physical Review Letters, 2012, 109(13): 137201.

[2] Wang Y Y, Song C, Wang G Y, Zeng F, Pan F. New Journal of Physics, 2014, 16: 123032.

[3] Wang Y Y, Song C, Wang G Y, Miao J H, Zeng F, Pan F. Advanced Functional Materials, 24: 6806-6810,

2014.

[4] Wang Y Y, Zhou X, Song C, Yan Y N, Zhou S M, Wang G Y, Chen C, Zeng F, Pan F. Advanced Materials,

27: 3196-3201. 2015.

[5] Han J H, Wang Y Y, Yin G F, Wang G Y, Pan F and Song C. Scientific Reports, 6, 31966, 2016.

[6] Zhou XJ, Yan YN, Jiang M; Cui B, Pan F. and Song C. 120, 1633-1639, 2016.

[7] Jiang M, Chen XZ, Zhou XJ, Cui B, Yan YN, Wu HQ, Pan F and Song Cheng. Applied Physics Letters,

108(20), 202404, 2016.

CV

Name: Pan Feng Nationality: Chinese

Affiliation: Tsinghua University Position: Professor

Telephone: +86-10-62772907


Mail address: School of Materials Science and Engineering, Tsinghua University, Beijing 100084, China

Education

1979-1983: Centre South University, Department of Materials

1983-1986: Beijing Institute of Aeronautic Materials

1981-1986: Tsinghua University, Department of Materials Science and Engineering

Working Experience

1986-1990: Beijing Institute of Aeronautic Materials, Engineer

1993-1996: Tsinghua University, Associate Professor

1996-present: Tsinghua University, Full Professor


1. F Pan, C Song, X J Liu, Y C Yang, F Zeng, Materials Science and Engineering R: Reports, 62, 1-35, 2008.

2. F Pan, S Gao, C Song, C Chen, F Zeng, Materials Sciences and Engineering R: Reports, 83, 1-59, 2014.

3. YC Yang, F Pan, Q Liu, M Liu, and F Zeng, Nano Letters, 9,1636-1642, 2009.

4. YY Wang, Xiang Zhou, Cheng Song, Yinuo Yan, Shiming Zhou, Guangyue Wang, Chao Chen, Fei Zeng and

Feng Pan, Advanced Materials, 27, 3196-3201, 2015

5. Li F, Song C, Gu YD, Cui B, Peng JJ, Wang GY, Pan F, Advanced Materials, 29, 1604052, 2017

29


AAO-Template Assisted Synthesis of Hierarchically Branched and Hybrid

One-Dimensional Nanoarchitectures for Devices

Guowen Meng*, Fangming Han

Institute of Solid State Physics, Chinese Academy of Sciences, Hefei, 230031, China

Branched and hybrid nanostructures impact the development of nanotechnology. The present synthetic

approaches, however, limit the degree of complexity and controllability. It has thus been a challenge to develop

generic approaches to branch and hybrid nanostructures. For branched nanotube (NT) and nanowire (NW), a

generic approach, based on the rational design of hierarchically branched nanochannels inside porous anodic

aluminum oxide (AAO) templates, has been developed to build a broad set of multiply branched NTs and NWs

[1-3]. For hetero-nanostructures, a generic synthetic approach to branched 2-segment NW/NT and 3-segment

NT/NW/NT heterojunctions has been realized via a combinatorial process of electrodepositing NWs in the

branched-channels, selectively etching part of the NWs within the branched-channels, and growing NTs on the

ends of the NWs within the nanochannels [4, 5]. These branched and hybrid nanoarchitectures have potentials in the

building of nanocircuits, nanodevices, and nanosystems.

For alumina-sheathed nanocables, the applied anodizing voltage is increased by a factor of 3 during Al

anodization, then 2/3 pores stop growing and the other 1/3 pores still grow. Then every “through-pore” is

surrounded by 6 capped-pores. By filling the “through-pores” as the nanocable “cores”, and wet-etching from

“capped-pores”, nanocables with “hexagonal prism” or “circular column” alumina-shell are built [6].

For dielectric capacitors with high energy density, a unique AAO membrane, with two sets of interdigitated

and isolated straight nanopores opening towards opposite planar surfaces, is first fabricated. By depositing

carbon-NTs in both sets of pores inside the AAO membrane, the new dielectric capacitor with 3D nanoscale

interdigital electrodes is realized. In the new capacitors, the large specific surface area of AAO can provide the

large capacitance, while uniform pore walls and hemispheric barrier layers can enhance the breakdown voltage.

As a result, a high energy density of 2 Wh/Kg that is to the value of a supercapacitor can be achieved [7], showing

promising potential in high density electrical energy storage for various applications.

References

[1] GW Meng, YJ Jung, AY Cao, R Vajtai and PM. Ajayan. Controlled fabrication of hierarchically branched

nanopores, nanotubes, and nanowires. Proc. Natl. Acad. Sci. U.S.A. 102, 2005, 7074-7078.

[2] BS Chen, QL Xu, XL Zhao, XG Zhu, and GW Meng*. Branched Silicon Nanotubes and Metal Nanowires

via AAO-Template-Assistant Approach. Adv. Funct. Mater.20, 2010, 3791-3796.

[3] XD Li, GW Meng*, QL Xu, XG Zhu, and AP Li. Controlled Synthesis of Germanium Nanowires and

Nanotubes with Variable Morphologies and Sizes. Nano Letters 11, 2011, 1704-1709.

[4] GW Meng*, FM Han, XL Zhao, BS Chen, Dachi Yang, et al. A General Synthetic Approach to

Interconnected Nanowire/nanotube and Nanotube/nanowire/nanotube Heterojunctions with Branched

Topology. Angew. Chem. Int. Ed. 48 (39), 2009, 7166-7170.

[5] BS Chen, GW Meng*, QL Xu, FM Han, and Z Zhang. Crystalline Silicon Nanotubes and Their Connections

30

with Gold Nanowires in Both Linear and Branched Topologies. ACS Nano 4 (12), 7105-7112 (2010).

[6] FM Han, GW Meng*, QL Xu, XL Zhao, BS Chen, et al. Alumina-sheathed Nanocables with Cores of

Various Structures and Materials. Angew. Chem. Int. Ed. 50, 2011, 2036-2040.

[7] FM Han, GW Meng*, F Zhou, L Song, BQ Wei, et al. Dielectric capacitors with three-dimensional

nanoscale interdigital electrodes for energy storage. Sci. Adv. 1, 2015, e1500605.

CV

Name: Guowen Meng Nationality: Chinese

Affiliation: Institute of Solid State Physics, CAS Position: Professor Director

Telephone: 86-0551-65592749 Facsimile: 86-0551-65591434


Mail address: Institute of Solid State Physics, Chinese Academy of Sciences, P. O. Box 1129, Hefei 23003, China

Education

Received B. Eng in 1984, M. Eng in 1987, and PhD in Materials Science & Engineering in 1996 from

Northwestern Polytechnic University, Xi’an, P. R. China.

Working Experience

Has been working in the Institute of Solid State Physics (CAS) since1996. Once worked in Dept. of M.S. & E. at

Rensselaer Polytechnic Institute (Troy, NY, USA) from Nov. 2002 to Dec. 2004.


1. XL Zhao, GW Meng*, QL Xu, et al. Adv. Mater. 22, 2637-2641 (2010).

2. ZL Huang, GW Meng*, et al. Adv. Mater. 22, 4136-4139 (2010).

3. HB Tang, GW Meng*, et al. Adv. Funct. Mater. 22, 218-224 (2012).

4. XJ Wang, GW Meng*, et al. Adv. Funct. Mater. 23, 5771-5777 (2013).

5. CH Zhu, Guowen Meng*, et al. Adv. Mater. 28, 4871-4876 (2016).

31


Nacre-Inspired Alumina Based Composites with Exceptional Mechanical

Properties

Hewei Zhao1 and Lin Guo1*

1School of Chemistry and Environment, Beihang University, Beijing 100191, P.R.

China

One of the most ambitious goals in materials engineering is the development of lightweight structural

materials with superior strength and toughness. Nacre is a typical light-weight and high-performance natural

material owing to its genius brick and mortar structure. But the toughness of it is poor, how to prepare the

composite with high-strength and high-toughness is a great challenge. Inspired by nacre, we develop a serious of

strategy for fabricating alumina based composites with inner nacre-like structure to achieve exceptional

mechanical properties. We report a simple hybrid freeze-casting method for the fabrication of novel alumina

(Al2O3)-cyanate ester (CE) composite materials with 3D interlocking skeleton structure1. The novel composite

shows light-weight (1.85 g/cm3), high flexural strength (300 MPa), high toughness (strain to failure of 5%) and

and shock-resistant simultaneously (Figure 1). Besides, we also have successfully fabricated ternary artificial

nacre (GO-AA-SCMC) reinforced by ultrathin amorphous alumina through vacuum assisted filtration method2.

The layer composite exhibits high strength (305 MPa) and high toughness (8.2 MJ/m3) at the same time (Figure

2). The design strategy inspired by nacre opens up a new path for developing light-weight yet high-strength and

tough materials.

Figure 1 – Morphology of 3D interlocking skeleton (a) and alumina/CE composites with inner 3D interlocking

structure (b). The composite shows low density, high strength and high toughness at the same time, which results

in its highest specific strength among alumina composites (c).

32

Figure 2 – Morphology of GO with ultrathin amorphous alumina (AA) in-situ grown (a) and GO-AA-SCMC

ternary artificial nacre (b). The novel artificial nacre shows high strength and toughness simultaneously (c).

References

[1] H. W. Zhao, Y. H. Yue, L. Guo, J. T. Wu, Y. W. Zhang, X. D. Li, S. C. Mao and X. D. Han, Adv. Mater.

2016, 28, 5099

[2] H. W. Zhao, Y. H. Yue, Y. W. Zhang, L. D. Li and L. Guo, Adv. Mater. 2016, 28, 2037

CV

Name: Lin Guo Nationality: Chinese

Affiliation: School of Chemistry and Environment, Beihang University

Position: Executive Dean

Telephone: 01082338162 Facsimile: 01082338162


Mail address: School of Chemistry and Environment, Beihang University, XueYuan Road No.37, Haidian District,

Beijing, China, 100191

Education

1981.09-1985.07 School of Chemistry, Northeast Normal University Bachelor

1989.09-1992.07 School of Chemistry, Jilin University Master

1994.02-1997.02 School of chemistry and materials, Beijing Institute of Technology Doctor

Working Experience

1997.02-1998.12 IHEP of Chinese academy of sciences Associate Researcher

1998.12-2001.03 School of materials science and technology, Beihang University Associate Professor.

2001.04-2008.06 School of materials science and technology, Beihang University Professor

2008.07-2008.06 School of Chemistry and Environment, Beihang University Professor


1. Wei Zhou and Lin Guo*, Iron Triad (Fe, Co, Ni) Nanomaterials: Structural Design, Functionalization and

their Applications, Chemical Society Reviews, 2015, 44, 6697

2. Lin Guo, Yun Liang Ji ,Huibin Xu, Paul Simon and Ziyu Wu, Regularly Shaped, Single-Crystalline Zno

Nanorods with Wurtzite Structure, Journal of The American Chemical Society, 2002,124,14864

3. Wei Zhou, Meng Yang, Lin Guo*, Yueming Li, Jinghong, Li and Shihe Yang, Hydrazine-Linked Convergent

Self-Assembly of Sophisticated Concave Polyhedrons of beta-Ni(OH)2 and NiO From Nanoplate Building

http://pubs.acs.org/author/Guo%2C+Linhttp://pubs.acs.org/author/Ji%2C+Yun+Lianghttp://pubs.acs.org/author/Xu%2C+Huibinhttp://pubs.acs.org/author/Simon%2C+Paulhttp://pubs.acs.org/author/Wu%2C+Ziyu

33

Blocks, Journal of The American Chemical Society, 2009, 131, 2959

4. Jianwei Nai, Yu Tian, Xin Guan and Lin Guo*, Pearson's Principle Inspired Generalized Strategy for The

Fabrication of Metal Hydroxide and Oxide Nanocages, Journal of The American Chemical Society, 2013,

135, 16082

5. Wei Zhou, Lijuan Lin, Dongyu Zhao and Lin Guo*, Synthesis of Nickel Bowl-Like Nanoparticles And Their

Doping for Inducing Planar Alignment of a Nematic Liquid Crystal, Journal of American Society, 2011, 133,

8389

34


Sensitivity Improvement of the Micro Hydrogen Sensor by Surface Modification

Jung-Sik Kim1

1Department of Materials Science and Engineering, University of Seoul, Seoul 02504,

Korea


In this study, highly sensitive hydrogen micro gas sensors of the multi-layer and micro-heater type were

designed and fabricated using the micro electro mechanical system (MEMS) process and palladium catalytic

metal as a sensing layer. The dimensions of the fabricated hydrogen gas sensor were about 5 mm×4 mm and the

sensing layer of palladium metal was deposited in the middle of the device. The surface of sensing palladium film

was modified to be the nano-honeycomb structure using an anodic aluminum oxide (AAO) template. Also,

another palladium film was modified to be the nano-hemisphere structure using nano-sized polystylene beads.

The sensitivities (Rs), which are the ratio of the relative resistance were significantly improved and reached

levels of 0.783% and 1.045% with 2,000 ppm H2 at 70°C for nano-honeycomb and nano-hemisphere structured

Pd films, respectively, on the other hand, the sensitivity was 0.638% for the plain Pd thin film. The improvement

of sensitivities for the nano-honeycomb and nano-hemisphere structured Pd films with respect to the plain Pd-thin

film was thought to be due to the nanoporous surface topographies of AAO and nano-sized polystyrene beads.

Keywords: Gas sensor, Hydrogen, MEMS, Palladium, Surface modification.

CV

Name: Jung-Sik Kim Nationality: Korea

Affiliation: University of Seoul Position: Professor



Mail address: Department of Materials Science and Engineering University of Seoul 163 Seoulsiripdaero,

Dongdaemun-gu, Seoul 02504, Korea

Education

1980-1987: B.S.: Materials Engineering in Hanyang University, Korea

1987-1992: MS, Ph.D.: Dept. of Materials Engineering, Purdue University, USA

Working Experience

1994-1995: Senior Researcher, KAERI, Korea

2016-2017: Vice President of Materials Research Society of Korea


1. Sensing properties for a microhydrogen sensor with modified palladium film, Sensors and Actuators B:

Chemical, vol.187, 540-545, (2013).

2. Photocatalytic characteristics for the nanocrystalline TiO2 on the Ag-doped CaAl2O4:(Eu, Nd) phosphor,

Applied Surface Science, vol.334, 151–156, (2015).

35

3. Effect of Additives on the Anisotropic Etching of Silicon by Using a TMAH Based Solution, Electronic

Materials Letters, vol.11(5), pp.871-880, (2015).

4. Highly sensitive dual-FET hydrogen gas sensors with a surface modified gate electrode, International

Journal of Hydrogen Energy, vol.40(35), pp.11756-11761, (2015).

5. Fabrication of SiO2/TiO2 double layer thin films with self-cleaning and photocatalytic properties, Journal of

Materials Science: Materials in Electronics, vol.27(10), pp.10082-10088 (2016).

36


Synthesis of Titania Nanotube and Nanostructure Carbon Composites via Solution

Chemical Routes and Their Physical Properties

Sunghun Eom1, Tomoyo Goto1, Sung Hun Chou1, Hisataka Nishida1, and Tohru

Sekino1*

1The Institute of Scientific and Industrial Research, Osaka University, Mihogaoka 8-1,

Ibaraki, Osaka 567-0047, JAPAN

E-mail: *[email protected]

As the promising low-dimensional nanomaterials, carbon nanotubes and graphenes are well known and

investigated. In addition, low-dimensional oxide semiconductor is also promising candidates as the

next-generation advanced functional materials. We have systematically investigated Titania nanotube (TiO2

nanotube, TNT) that has one-dimensional (1D) hollow tubular structure. This unique nanostructured material has

high surface area, good photocatalytic property due to the long lifetime of photo-activated electrons/halls and

active species (such as radicals) on 1D TNT, and high molecular adsorption capacity [1-3]. However, electrical

conductivity, i.e. mobility and career density of Titania is rather low among various semiconductor oxide, which

is fundamental property of TiO2-based crystal. And this is also the essential for the TNTs. Therefore, enhancing

semiconductive characteristics of TNT is mandatory required to utilize it as for the advanced

energy/enviroment/device application. In this study, we have attempted to fabricate

low-dimensional/low-dimensional functional nanocomposites using Titania nanotubes and carbon nanomaterials.

Special emphases have placed to clarify the correlation between low-dimensional nanostructures of individual

phases and their physical properties.

Basic TNT synthesis will be carried out based on the solution chemical route. Typically, TiO2 raw powder is

put into 10 M NaOH aqueous solution and refluxed at 110°C for 24 ~48 hr. After the reaction, the obtained

products are washed by distilled water many times to eliminate alkaline species and neutralized, then dried in an

oven at 60 °C for one day. TNT/Carbom nanocomposites were synthesized by in-situ routes. Typical procedure

for the in-situ immobilization was similar to the processing described before for the TNT synthesis: here

multi-wall CNTs (MW-CNT) or graphene (GO) powders were put into reaction vessel for 0-30 wt% to TiO2.

Through the in-situ processing, TNT/CNT and TNT/GO low-dimensional nanocomposites have been

synthesized. It was found that TNT tended to cover the CNT to form 1D/1D core-shell nanocomposites. On the

other hand, TNT was formed to cover the 2-d nanostructured GO to make sheet-like morphology. Electrical

conductivity of these powder samples were measured, and it was found that the conductivity increased by the

nano-compositing TNT with CNT and GO as well, which implied us that the charge transfer might be enhanced

much for the advanced TNT/carbon nanomaterials. Materials processing, nano-hybrid structure,

phyical-chemical, and electrical properties of these unique low-D/low-D nanocomposites will be discussed in

detail.

References

[1] T. Kasuga, M. Hiramatsu, A. Hoson, T. Sekino, K. Niihara, Langmuir, 14, 3160-3163(1998).

[2] J.-Y. Kim, T. Sekino, S.-I. Tanaka, J. Mater. Sci., 46, 1749–1757(2011).

[3] T. Sekino, Chapter 2 in Inorganic and Metallic Nanotubular Materials- Recent Technologies and

Applications-, Tsuyoshi Kijima Ed., Springer-Verlag, June 2010, pp.17-32.

37

CV

Name: Tohru Sekino Nationality: Japan

Affiliation: The Institute of Scientific and Industrial Research (ISIR), Osaka University

Position: Professor



Mail address: Mihogaoka 8-1, Ibaraki, Osaka 567-0047, Japan

Education

1988.03: B.S.: Department of Applied Chemistry, Faculty of Engineering, Tohoku University

1990.03: M.S.: Department of Materials Chemistry, Faculty of Engineering, Tohoku University

1997.05: Ph.D.: Dr. of Engineering, Osaka University

Working Experience

1990.04 ~ 1999.03: Research Associate, ISIR, Osaka University

1999.04 ~ 2007.10: Associate Professor, ISIR, Osaka University

2007.11 ~ 2014.03: Associate Professor, IMRAM, Tohoku University

2008.04 ~ 2013.09: Part-time Lecturer, Sendai National College of Technology

2013.04 ~ 2013.09: Lecturer (Part-time), Nagasaki University

2014.04 ~ present: Professor, ISIR, Osaka University


1. “Nanostructured Ti6Al4V alloy fabricated using modified alkali-heat treatment: Characterization and cell

adhesion”, Y. Su, S. Komasa, T. Sekino, H. Nishizaki, and J. Okazaki, Materials Science and Engineering

C, Volume 59, 617-623(2016).

2. “Application of Titanium Dioxide Nanotubes to Tooth Whitening”, Obito Komatsu, Hisataka Nishida,

Tohru Sekino, and Kazuyo Yamamoto, Nano Biomedicine, 6(2), 63-72 (2014).

3. “Nanostructures and physicochemical properties of Pt nanoparticle-loaded titania nanotubes synthesized

by photoreduction method”, D. J. Park, *T. Sekino, S. Tsukuda, S.-I. Tanaka, J. Ceram. Soc. Japan, 120,

307-310 (2012).

4. "Influence of the size-controlled TiO2 nanotubes fabricated by low-temperature chemical synthesis on the

dye-sensitized solar cell properties", J.-Y. Kim, T. Sekino, S.-I. Tanaka, J. Mater. Sci., vol. 46, issue 6,

1749–1757(2011).

5. "Formation of titanium oxide nanotube", T. Kasuga, M. Hiramatsu, A. Hoson, T. Sekino, K. Niihara,

Langmuir, Vol.14, No.12, 3160-3163(1998).

38


Development of Next-Generation High-Performance Metallic Materials via

Strengthening from Fully Coherent Nano-Precipitates

Z. P. Lu

State Key Laboratory for Advanced Metals and Materials, University of Science and

Technology Beijing, Beijing 100083, China

Although metallic materials have been utilized by human being for thousands of years, recent social and

economic development require novel superior alloys for lightweight design strategies and advanced energy

applications. However, most conventional metallurgical approaches for increasing strength usually reduce ductility,

an effect referred to as the strength-ductility trade-off. In this talk, our recent research work on development of

advanced metallic materials including high-performance steels, high-entropy alloys via strengthening from

massive coherent nanoprecipitates will be summarized:

1) Maraging steels, are a class of high-strength materials with the potential for meeting the increasing demands

from modern industries, however, their outstanding strength originates from semi-coherent precipitates which

unavoidably exhibit a heterogeneous distribution that create large coherency strains, which in turn promote crack

initiation under load. In our study, a counterintuitive strategy for the design of ultra-high strength alloys by

massive and highly dispersed second-phase nanoprecipitation with minimal lattice misfit was proposed [1]. Fully

coherent precipitates, showing very low lattice misfit with the matrix and high anti-phase boundary energy,

effectively strengthen alloys without sacrificing ductility. The minimized elastic misfit strain around the particles

does not contribute much to the dislocation interaction which is typically needed for strength increase. Instead the

chemical ordering effect which creates backstresses when precipitates are cut by dislocations was exploited as the

new strengthening mechanism. With this approach, a class of steelswith a strength up to 2.2 GPa and good

ductility (~8.2 %) were created.

2) High-entropy alloys are an emerging research area for metallic materials and have attracted extensive

attention recently due to their interesting mechanical, physical and structural properties. Unlike in conventional

metallic materials, the traditional “solutes and solvents” lose their original meaning in these equal molars or near

equal molar alloys. Therefore, the strengthening behavior and underlying mechanisms in these highly

concentrated alloys became important both scientifically and technologically. In this talk, focus will be placed on

presentation of our recent research work on precipitation hardening behavior of fully coherent nanoparticles in fcc

FeCoNiCrMn high-entropy alloys [2,3]. Precipitation behavior and structural stability of the nanoparticles and their

effects on mechanical properties will be presented. The underlying strengthening mechanisms responsible for the

improved mechanical properties will also be discussed in detail.

References

[1] S. H. Jiang et al., Nature, Nature 544 (7651), 460-464, 2017.

[2] J. Y. He et al., Acta Materialia 62, 105-113, 2014. ESI Highly Cited Paper

[3] J. Y. He et al., Acta Materialia 102, 187-196, 2016. ESI Highly Cited Paper

39

CV

Name: Zhaoping Lu Nationality: Chinese

Affiliation: University of Science and Technology Beijing Position: Professor

Telephone: 010-82375387 Facsimile: 010-62333447


Mail address: State Key Laboratory for Advanced Metals and Metallic Materials, University of Science and

Technology Beijing, 30 Xueyuan Rd, Haidian District, Beijing 100083

Education

2001-- Ph. D.: Materials Science, National University of Singapore, Singapore

1995-- M. E.: Materials Science and Engineering, Huazhong University of Science and Technology, P. R. China

1992-- B. E.: Materials Science and Engineering, Huazhong University of Science and Technology, P. R. China

Working Experience

2007-present: Professor, University of Science and Technology Beijing Director, State Key Laboratory for

Advanced Metals and Materials

2004-2006: Research staff, Metals and Ceramic Division, Oak Ridge National Laboratory

2001-2004: Postdoctoral fellow, Metals and Ceramic Division, Oak Ridge National Laboratory

1999-2001: R&D engineer, Kulicke & Soffa Industries Inc., Singapore


1. Sensing properties for a microhydrogen sensor with modified palladium film, Sensors and Actuators B:

Chemical, vol.187, 540-545, (2013).

2. Photocatalytic characteristics for the nanocrystalline TiO2 on the Ag-doped CaAl2O4:(Eu, Nd) phosphor,

Applied Surface Science, vol.334, 151–156, (2015).

3. Effect of Additives on the Anisotropic Etching of Silicon by Using a TMAH Based Solution, Electronic

Materials Letters, vol.11(5), pp.871-880, (2015).

4. Highly sensitive dual-FET hydrogen gas sensors with a surface modified gate electrode, International

Journal of Hydrogen Energy, vol. 40(35), pp.11756-11761, (2015).

5. Fabrication of SiO2/TiO2 double layer thin films with self-cleaning and photocatalytic properties, Journal of

Materials Science: Materials in Electronics, vol. 27(10), pp.10082-10088 (2016).

40


Fabrication of RGO Nanocomposite Materials Based on Solution Process Platform

and Their Applications

Woo-Gwang Jung

School of Advanced Materials Engineering, Kookmin University, Korea


Reduced graphene oxide (RGO) can be expected to improve the photocatalytic performance of

semiconductor photocatalysts because of its electron mobility and high specific surface area. Zinc oxide and

titanium oxide is good photocatalyst. But sometime the activity has decreased because of electron-hole pair

recombination. Combination of two or more photocatalyst may help to get rid of this problem by their staircase

band structure. In this work, we combined ZnO with TiO2 and RGO to synthesize a ternary composite by one pot

synthesis method. The amount of GO was varied to know the effect of RGO in the photocatalysis. The rod shaped

ZnO and round shaped TiO2 was densely dispersed on thin RGO film. With the increase of amount of RGO in the

composite, the photocatalytic activity of the composite was increasing. We found that there is a significant change

in photocatalytic activity after adding RGO with ZnO and TiO2. The maximum photoreduction of Cr (VI) was

63% at 120 min with 42 wt% RGO containing composite under UV light irradiation. The mechanism of the

photocatalytic activity of RGO-TiO2-ZnO was investigated with the combination of previously synthesized

RGO-CdS. There was no significant decay of photocurrent for GTZ nanocomposites, while ZnO showed decay

with time.

Keywords: RGO, Nanocomposite, Photocatalyst, Chemical sensor, Supercapacitor.

CV

Name: Woo Gwang Jung Nationality: Korea

Affiliation: Kookmin University Position: Professor



Mail address: School of Advanced Materials Engineering Kookmin University 77 Jeongneung-ro, Seongbuk-gu,

Seoul, 02727, Korea

Education

1978-1982 B.S.: Metallurgical Engineering in Hanyang University, Korea

1983-1985 M.S.: Metallurgical Engineering in Osaka University, Japan

1985-1988 Ph.D.: Metallurgical Engineering in Osaka University, Japan

Working Experience

1989-1991 Research Associate, The University of Chicago, USA

1991-1994 Research Institute of Industrial Science and Technology (RIST), Korea

1994-1998 POSCO Technical Research Laboratories, Korea

Present: Vice President, MRS-K

41


1. Facile and safe graphene prepara

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Chinese Materials Conference 2017 2017 China-Japan-Korea ... · Guanjun QIAO Jing SUN Xiaowei YIN Changan WANG Tae-Ho Kim Invited Invited Keynote Invited Invited Haijun ZHANG Kyung