Orientation for Energy Science and Engineering New Students

Tetsuya Suekane Director of Energy Science and Engineering Course

tsuekane@es.titech.ac.jp Sept. 26, 2018

Version Date: April 20, 2016, Rev 2. Sept. 23, 20161

Outline•  Opening •  Requirements for acquiring doctoral/master’s degrees

(20 minutes) •  Slides are translated from Japanese into English

2

（科目群 ) Classification (科目区分）Type Course category

（教養科目群）Liberal arts and basic science courses

（文系教養科目）

Humanities and social science courses （英語科目）

English language courses （第二外国語科目）

Second foreign language courses （日本語・日本文化科目）

Japanese language and culture courses （教職科目）

Teacher education courses （キャリア科目）

Career development courses （広域教養科目）

Breadth courses

（専門科目群） Core courses

（講究科目）

Research seminars （研究関連科目）

Research-related courses （専門科目）

Major courses

Goals of Energy Science and Engineering Course

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●Philosophy and Goal of Energy Science and Engineering Course Energy-related research and economic development has grown world-wide and become an important issue for society. Accordingly, there is a greater need to develop this interdisciplinary academic field into “multidimensional energy theory” to fuse/reconstruct energy-related academics, enable a comprehensive view and realize efficient utilization of energy knowledge. It is also necessary to cultivate professionals and leaders who have acquired expertise in multidimensional energy theory. In the Graduate Majors in Energy Science and Engineering, we cultivate individuals to lead innovation and contribute to society with advanced expertise based on the disciplines of physics, chemistry, materials science, mechanical engineering, and electrical engineering. Such individuals possess the comprehensive skills to handle ever-changing energy problems from a multidimensional energy theory perspective, with independent problem development/solving skills and international leadership skills.

How can professionals acquire theory shared by different energy fields while maintaining expertise in the basics of each discipline? What is multidimensional energy theory and how does it contribute to achieving this goal? 4

5

•  Energy principles consist of knowledge nodes spanning different fields (academic majors)

Shared theory taught in Energy related courses “multidimensional energy theory”

－Reorganization of energy knowledge－

Utilization of Knowledge necessary for advanced research

Classification (reorganization)Deep understanding necessary to have a comprehensive view of energy knowledge

through analogy with knowledge fields

　What is the same? What is different?

Tremendous amount of knowledge in different fields makes it difficult to ascertain comprehensive knowledge from a bird’s viewpoint

Fuel cells Solar cells Internal combustion

Diagram showing relationship between Energy Interdisciplinary and Major Related Courses (Master’s Program)

　　*Energy System Theory 1*, Economy of Energy System*　　

　　 Interdisciplinary principles of energy devices 1*, 2*　　

Interdisciplinary scientific principles of energy 1 *, 2*　

　　 Interdisciplinary Energy Materials Science 1 *, 2*　　

InterdisciplinaryScien0ficPrinciplesofEnergyCourses

Courses in 400 series

Energy Innovation Collaborative Project

Discipline based Majors Chemical Science and Engineering

Mechanical Engineering

Electrical and Electronic Engineering

Materials Science and Engineering

Chemistry

Courses in 500 series

Special lecture of economics and politics in energy

At least 4 credits from Energy Theory Lecture Group marked with an asterisk (*)ANDAt least 4 credits in Discipline Theory Lecture Group in student’s affiliated department

Recent Technologies of Fuel Cells, Solar Cells, Storage Batteries, and Energy System

Advanced Scientific Technology in Energy and Environment

6

Energy Science and Engineering

•  Many different issues/key topics Normally graduate students focus their research on one single topic or technology.

•  Goal •  Cultivate professionals who are highly committed to contributing to

society and who are capable of leading innovation •  Advanced expertise in the energy field based on the

disciplines of physics, chemistry, materials science, mechanical engineering, and electrical engineering

•  Possess the comprehensive skills to handle ever-changing energy problems from a multidimensional energy theory perspective

•  Independent problem development/solving skills •  International leadership skills

Solar cellFuel cell

Secondary battery

Energy mix Hydrogen society

FIT

Fuel cell vehicle

CO2 reductionGlobal warming

CCS

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(Thermodynamics, electrochemistry, response kinetics, quantum chemistry, solid-state physics, solid-state chemistry…)

Fuel cell

Fuel reformer

Heat exchanger

etc.

Solar cell system

Solar cell

etc.

etc.

Nuclear power system

Reactors

Heat exchanger

Turbine

etc.

Radiator

etc.

Materials

Materials

Materials Materials

Materials

Desulfurizer

Thermal power system

Gas turbine

Heat exchanger

Interdisciplinary Energy Materials Science Interdisciplinary principles of energy devices

Fuel Cell system

Materials

Secondary battery

PCS

Storage battery

Heat Engine system

Engine

PCS

Exhaust gas purifier

Electricity Storage system

Interdisciplinary scientific principles of energy

Diagram of Energy Related Course

etc.

Energy System Theory 1

Economics of energy

systems, Special lecture of economics and politics in

energy

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Curriculum for Energy Science and Engineering

9

Master’s Program

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Course Key Features

•  Energy Interdisciplinary Principle Courses •  Courses for learning energy principals

(multidimensional energy theory) which is shared among energy fields

•  Major related courses •  Lectures on advanced topics based the

following disciplines: physics, chemistry, materials science, mechanical engineering, or electrical engineering

•  XX section of Energy Science and Engineering in the XX field

•  Research Seminars •  Seminars, subscription to academic papers,

etc.

Energy Interdisciplinary Principle Courses

Major Related Courses

Research Seminars

Energy problems

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Overview of Interdisciplinary Energy Courses (required)•  Interdisciplinary scientific principles of energy 1, 2

•  Basics are applied, but application is not applied.•  (1) Learning for thermodynamics and quantum mechanics •  (2) Mass transfer, lattice oscillation; optical properties of energy and materials

•  Interdisciplinary principles of energy devices 1, 2 •  (1) Devices focusing on heat

•  Heat engine, nuclear power, heat pumps, electrical devices •  (2) Devices focusing on light and electrochemistry

•  Fuel cells, solar cells, storage devices, light-emitting devices

•  Interdisciplinary Energy Materials Science 1,2 •  (1) Light in materials

•  Metallic materials, semiconductors, dielectric materials, superconductive materials •  (2) Heat in materials

•  High-temperature materials, low-temperature materials, catalysts, ion conduction

•  Energy system theory •  New social mechanisms, etc. (e.g. Hydrogen Society)

•  Economy of energy system •  Why are electric fees about 27 yen per kWh? •  Are you familiar with life cycle assessment and the input-output table? •  What is the status of energy development policies in Japan? •  What is the mechanism and explanation for consensus building based on

wind power generation? 12

Understanding fundamental theory required for energy conversion

１. Thermodynamics Calculate maximum theoretical value of energy Conversion.

3. Electrochemistry

2. Kinetics

Rate of energy conversion

4. Material Science (Solid-state chemistry Polymer science, Ceramics, Solid-state physics Metallurgy etc.)　

Materials research and development

Response and transport phenomena

13

Fuelcombus0ongovernedbyserialandparallelprocesses

Fundamentals of electron behavior in solids (quantum mechanics, bands…) Lattice vibration affects conduction (phonon) and optical properities of electrons in solids

Requirements for Master’s Program of Energy Science and Engineering

Course classification Required credits Elective credits No. of creditsRelation with

studied content

Liberal Arts

and B

asic Science C

ourses

Humanities and social science courses

・At least 2 from 400-levels・At least 1 credit from 500-levels

At least 5 credits

D

Career development courses

・At least 2 credits from 400 and 500-levels

C, D, E

Other

Core courses

Research Seminars

Two credits from each of the following: Seminar in Energy Science S1Seminar in Energy Science F1Seminar in Energy Science S2Seminar in Energy Science F2Total of 8 credits

At least 25 credits from specialized courses of the

standard learning curriculum

B, C, D, E

Research related courses

B, C, D, E

Major courses

・Atleast4creditsfromInterdisciplinaryScien0ficPrinciplesofEnergyCoursesand・Atleast4creditsfrom energycourse in student’s affiliateddepartment See course notes

A, B

Core courses other than the standard learning curriculum or research related courses

Total credits for graduation The student must meet the requirements listed above and obtain at least 30 credits

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Number of credits which must be taken from the Core Courses (at least 25 credits)

Research Seminars (8 credits)

Energy Interdisciplinary Principle Courses ・Required (4 credits selected from among 8 credits)・Electives 　　・Opening of Energy Science and Engineering 　　・Opening of Global Engineering for Development, Environment and

Society

Major Related Courses (total of about 200 courses) ・Major Courses in student’s affiliated department (4 credits) ・Major Courses of other departments

The remaining 9 credits are taken from the following (more than 200 courses)

(minimum requirements)

15

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Requirements for Master’s Program of Energy Science and Engineering

Note：Atleast4creditsfromenergycourseinstudent’saffiliateddepartmentForstudentsinDepartmentofChemistry,aminimumof4creditsfromtheChemistrymajorcourses(*),andforstudentsintheDepartmentofTransdisciplinaryScienceandEngineering,aminimumof4creditsfromenergymajorcoursesinotherdepartments(eitheroneormore)thatofferGraduateMajorinEnergyScienceandEngineering.

Structure of Core Courses for the Master’s Program•  Core courses (at least 25 credits)

•  Research Seminars (at least 8 credits) •  Major Courses

•  Required (each 1-0-0, at least 4 credits from among the 8 credits) •  Interdisciplinary scientific principles of energy 1, 2 •  Interdisciplinary principles of energy devices 1, 2 •  Interdisciplinary Energy Materials Science 1, 2 •  Energy System Theory •  Economy of Energy System

•  Electives •  Opening of Energy Science and Engineering

•  Recent technologies of fuel cells, solar cells, butteries and energy system(2-0-0) •  Advanced Science and Technology in Energy and Environment (2-0-0) •  Special lecture of economics and politics in energy (1-0-0) •  Energy innovation co-creative project(0-0-1): Intermediate presentation held in winter as a poster

session •  Opening of Global Engineering for Development, Environment and Society

•  Technologies for Energy and Resource Utilization (1-0-0) •  Project Design & Management S(0-1-1) •  Project Design & Management F(0-1-1) •  The economics and systems analysis of environment, resources and technology (1-0-0)

•  Major Related (approx. 200 courses) •  Composed from courses unique to Energy Science and Engineering specialized courses of each

department. •  From among these courses, at least 4 credits from the Major Courses in the student’s affiliated

department

l  25 credits – Research Seminars: 8 credits – Major Courses: 4 credits (required) – Major Related Courses: 4 credits = 9 credits

l  At the very least, the remaining 9 credits must be taken from the Core Courses.17

Career development courses - master•  Master’sstudentsarerequiredtoacquirethenecessarycreditsinthecareerdevelopmentcourseswithfulfillingalltheGraduateAPributes(GA),bothC0MandC1M,morethan2credits.

•  Energycourseprovidessomesubjectswhichcouldbetransfertothiscredits.

•  EnergyCourse•  Energyinnova0onco-crea0veproject（posterpresenta0on，1credit）C1M•  EnergyengineeringinternshipA，B　(needcontractinadvance)　C1M•  Introduc0ontointellectualpropertysystem 研究者向け特許論文等知財の

基礎　C0M,C1M

•  See(学修案内　表M3　エネルギーコースキャリア対応科目を参照)

※Ifyoutransfermajorrelatedsubjecttocareersubject,thecreditsarecountedforcareersubjectonly.

C0M:Abletodelineateone’scareerplanclearlyandrecognizetheskillstomaterializetheplan,alsoconsideringitsrela0onstothesociety.

C1M:Abletou0lizeitsownexper0setothedevelopmentofacademiaandtechnology,andworkwithotherswithdifferentexper0setocontributetoproblem-solving. 18

「9月入学の大学院生（博士後期/修士）向け、IIDPキャリア科目履修について/Career Development Course Instruction & Orientation」

東京工業大学イノベーション人材養成機構（IIDP） Career Development Course Orientation

　　　IIDPキャリア科目履修オリエンテーション

大学院修士課程／博士後期課程修了にはキャリア科目の単位取得が必要です。どのようにキャリア科目を履修すべきか、キャリア科目を全学に提供して

いるイノベーション人材養成機構（IIDP）が説明します。

How to study & register the career development courses in order to complete your graduate program

博士後期課程学生のキャリア科目履修に必要な「アカデミックリーダー教育院（ALP）」「プロダクティブリーダー教育院（PLP)」登録も解説！

2018. 9. 27 （Thu.） 10：45～11：30 すずかけ台（Suzukakedai）　B223

13：20～14：05 　大岡山（Ookayama）　H101※The same explanation is given in English and Japanese for both Master’s and Doctoral program students.※9/28 (金）［修・7限すJ234］、10/2（火）［博・5限大S515］、 10/2（火）［修博・5限　 すJ221］、 10/3（水）［修・5限大W541］のIIDP開講科目講義冒頭でも、対応す る修士/博士への説明を行います。※オリエン資料はIIDPサイトからダウンロードできます。 Orientation materials can be downloaded from IIDP Web site.

9月入学の大学院生(修士課程/博士後期課程)対象Newly enrolled Graduate Students in Sep., 2018

Japanese /English

直前に予定変更等の場合があるのでIIDPサイトを必ず確認して下さい PleasevisitIIDPWebsiteandconfirmthelatestinfo.Venue,0me,etc.mightbechanged.

「IIDP」で検索！

主催：東京工業大学イノベーション人材養成機構(IIDP)　　iidpinfo@jim.titech.ac.jp

19

Career Development Course Instruction & Orientation

キャリア科目情報の取得方法※IIDPのWebにも解説あり（「IIDP」で検索！h%p://www.iidp.-tech.ac.jp）

-------------------------------------（履修手続）教務Webシステムで行う。

東工大ポータルにログインし、メニューから「教務Webシステム」を選択。履修科目登録を行う。 

（１）各コースの修了要件の確認方法

「大学院学修案内」より、「各コース案内」で所属コースの修了要件を確認hPp://www.0tech.ac.jp/guide/guide_30/graduate/index.html 

（２）キャリア科目

キャリア科目には、各コースが開講する自コース学生向けのものと、IIDPが開講する全学学生向けの

ものがある。（さらに、イノベーション科学コース／技術経営専門職学位課程が開講して全学に公開す

るキャリア科目も、同コース所属学生優先ですが、枠があれば履修可能。）「30年度IIDP開講キャリア科目一覧」はIIDPサイトで確認してください。 

（３）シラバス

OCW（hPp://www.ocw.0tech.ac.jp/index.php）トップページで「講義検索」を行い、該当ページを探す。担当教員、日程、講義室などはシラバスを参照する。

--------------------------------------------------- How to study and register the career development courses. All the graduate students in TokyoTech are needed to study the career development courses in order to complete the graduate degree program. (general guideline: Master = 2GAs with 2 credits. Doctor = 4GAs with 4 credits of the career development courses) Please refer to your department study guide, syllabus, etc. and confirm your degree program completion condition. The department you belong to establishes the department's original career development courses for the department’s students. IIDP establishes career development courses for all department students. You can take the career development courses which either your department or IIDP provides. i) Confirm your department’s study guide. ii) Visit the TokyoTech Portal and register courses by accessing to “ Web system for students and faculty”.

当日説明します Will be instructed in Japanese/English

直前に予定変更等の場合があるのでIIDPサイトを必ず確認して下さい PleasevisitIIDPWebsiteandconfirmthelatestinfo.Venue,0me,etc.mightbechanged.

「IIDP」で検索！

20

Career development courses

• Career development courses •  Listed in “Enrollment Guide for Humanities and Social

Science Courses” •  At the URL http://www.titech.ac.jp/guide/guide_28/English_F/

index.html, click on “Career development courses” in section “Liberal Arts and Basic Science Courses”

• Career development related courses in major •  Specialized Subjects which are recognized as career

development courses •  In the Master’s Program and Doctoral Program, career

related courses are specified by each department.

21

ENR.A401.A　Interdisciplinary scientific principles 1

A：Energy Interdisciplinary Principle Courses (required course) B：Energy Interdisciplinary Principle Courses (elective course) H, E：Department of Chemical Science and Engineering; Major Related Courses I：Department of Chemistry; Major Related Courses J：Department of Materials Science and Engineering; Major Related Courses K：Department of Mechanical Engineering; Major Related Courses L：Department of Electrical and Electronic Engineering; Major Related Courses Z：Research Seminars

Example of Energy Science and Engineering course code

Required courses of the Energy Interdisciplinary Principle Courses are denoted by an “A”, other elective courses are denoted by an “L”

How to read course codes

22

Doctoral Program

23

Requirements for Doctoral Program of Energy Science and Engineering

Course classification Required credits Elective credits

No. of credits

Relation with studied content Notes

Liberal Arts and

Basic Science

Courses

Humanities and social science courses

At least 2 credits

At least 6 credits

B

Career development courses

At least 4 credits C, D, E

Other  

Core courses

Seminars

Two credits from following: Seminars in Energy Science S3Seminar in Energy Science F3Seminar in Energy Science S4Seminar in Energy Science F4Seminar in Energy Science S5Seminar in Energy Science F5Total of 12 credits

At least 18 credits from

major courses

A, B, C, D, E

Research related courses C, D, E

Specialized courses At least 6

credits A, B, C, D

Total credits for graduation The student must obtain the requirements listed above and obtain at least 24 credits

24

Structure of Core Courses for the Doctoral Program•  Accreditation for normal research activities

•  At least 6 credits

•  Lecture courses •  Students take lectures given by native English faculty and acquire the skills to write English papers. These

courses are useful when writing papers and enrollment is highly recommended by faculty. •  Academic Writing　A 1 credit　1Q •  Academic Writing　B　1 credit　2Q

•  Students acquire presentation skills for domestic conferences and international conferences through preparation, presentation practice, response to questions, and giving actual presentations/handling actual Q&A.

•  Practical Presentation A 1 credit　(1Q to 4Q)

•  Practical Presentation B 1 credit　(1Q to 4Q)

•  Practical Presentation C 1 credit　(1Q to 4Q)

•  International scientific presentation A 1 credit (1Q to 4Q)

•  International scientific presentation B 1 credit (1Q to 4Q)

•  International scientific presentation C 1 credit (1Q to 4Q)

•  Students acquire teaching skills such as instructing younger students, RA activities, mock lectures, etc.

•  Academic teaching 1 credit (1Q to 4Q)

•  Acquire the skills for structuring and executing research through conceptual presentations, progress reports, etc. for Doctoral research.

•  Practical research in energy science A 1 credit (1Q to 4Q)

•  Practical research in energy science B 1 credit (1Q to 4Q)

•  Acquire international skills and communication ability through internships.

•  International energy project 　2 credits　 (1Q to 4Q) 　　　　　　　　　　　　　　　　　　　　　　　　　　　　　　　　　　 25

Degree Course Milestones

26

Degree Milestones•  In Master's or Doctor’s Program, interim research-progress presentations are conducted

with his/her department. •  Demonstrate acquisition of specialized knowledge and communication skills

•  Master or Doctor thesis defense conducted in the Energy Science and Engineering program.

M1

M2

Based upon dept.

Schedule for M thesis presentation

Week 1

Week 2

Week 3

Intermediate presentation with faculty evaluation (assures Specialization)

Orientation

Final presentation

Interim presentation D1

D2

D3

Conceptual presentation with faculty evaluation (assures Specialization)

Orientation

For examiners

Public Hearing

Final exam

Master's Program Doctoral Program

Interim presentation l  A poster presentation held during 1st year of Master's

Program for discussion with students and dept. faculty. l  Energy Innovation Collaborative Project (1 credit)

Milestones for acquiring degree

Interim presentation (TBD)

Possible PBL activity

27

Master’sThesisResearch

１① １② １③ １④ ２① ２② ２③ ２④

SeminarinenergyscienceF1SeminarinenergyscienceS1 SeminarinenergyscienceS2 SeminarinenergyscienceF2ResearchSeminars

MajorCourses(DepartmentofChemicalScienceandEngineering)

AdvancedOrganicElectrochemistry

TopicsinOrganicElectronics

TopicsinAppliedElectrochemistry

TopicsinProper0esofSemiconductors

AdvancedPhotochemistryI

AdvancedPhotochemistryII

AdvancedElectrochemistryI

AdvancedElectrochemistryII

AdvancedInorganicMaterialsChemistryI

AdvancedInorganicMaterialsChemistryII

AdvancedSolidStateChemistryOrientedforEnergyand

EnvironmentIssuesIAdvancedSolidStateChemistryOrientedforEnergyand

EnvironmentIssuesII

AdvancedChemicalMaterialsforEnergy

IssuesI AdvancedChemicalMaterialsforEnergy

IssuesII

AdvancedFunc0onalPolymerMaterialsI

AdvancedFunc0onalPolymerMaterialsII

AdvancedPolymerDesignforEnergy

Meterials

AdvancedCourseinMacromolecularMaterialsII

Appliedchemistry　１①～２④

【Polymerscience】

【Chemicalengineering】

【Appliedchemisitry】

AdvancedStrategicOrganicSynthesis

AdvancedNano-MaterialsChemistryI

AdvancedNano-MaterialsChemistryII

Physico-ChemicalPropertyAnalysisinChemicalEngineering

AdvancedChemicalEquipmentDesign

ProcessSystemsEngineering

AdvancedChemicalReac0on

Engineering

AdvancedSepa-ra0onOpera0on

ProcessDynamicsandControl

AdvancedPolymerSynthesisII

AdvancedPolymerProper0esI

AdvancedPolymerProper0esII

AdvancedPolymerStructuresI

AdvancedPolymerStructuresII

AdvancedPolymerReac0ons

AdvancedOrganicMaterialsChemistry

AdvancedSupra-molecularChemistry

MaterialCycleAnalysis

AdvancedInstru-mentalAnalysis

AdvancedOrgano-metallicChemistryandCatalysisI

AdvancedCataly0cReac0onsI

AdvancedCataly0cReac0onsII

AdvancedChemistryof

Transi0onMetalComplexesI

AdvancedOrgano-metallicChemistryandCatalysisI

AdvancedElectrochemistryI

AdvancedElectrochemistryII

AdvancedChemistryof

Transi0onMetalComplexesII

Systema0cMaterialDesign

Methodology

Systema0cMaterialDesign

Methodology

ChemicalEngineeringinGlobalBusiness

AdvancedPolymerScienceI

AdvancedPolymerScienceII

AdvancedPolymerProcessing

AdvancedInternshipinChemicalScienceand

Engineering

EnvironmentPreserva0onandChemicalSafetyI

EnvironmentPreserva0onandChemicalSafetyII

AdvancedDataAnalysis

Presenta0onPrac0ce

Scien0ficEthics【Researchseminars】Researchseminars　１①～２④

【DepartmentofChemicalScienceandEngineering,MajorofEnergyScienceandEngineering(Master’sprogram）】

Interdisciplinaryscien0ficprinciplesofenergy1

Interdisciplinaryscien0ficprinciplesofenergy2

Interdisciplinaryprinciplesofenergydevices1

Interdisciplinaryprinciplesofenergydevices2 InterdisciplinaryEnergy

MaterialsScience1InterdisciplinaryEnergyMaterialsScience2

Energysystemtheory Economyofenergysystem

Research-RelatedCourses Energyinnova0onco-crea0veproject

InterdisciplinaryScien0ficPrinciplesofEnergyCourses

RequiredCourses Elec0veCourses

Redframe:MajorCoursesBlackframe:Research-RelatedCourses

Polymerscience①～２④

Chemicalengineering　１①～２④

Geochemistry

CatalysisfortheEnvironmentalIssues

Environmental　Analy0calChemistry

AdvancedCoordi-na0onChemistry

EnvironmentalChemistry

AdvancedEnergyTransferOpera0on

Introduc0ontoChemical

Engineering(Basics)Introduc0onto

ChemicalEngineering(Unit

Opera0on)

AdvancedNanoscale

ChemicalProcess

TransportPhenomenaand

Opera0on

Computa0onalFluidDynamics

AdvancedCourseinMacromolecularMaterialsI

Introduc0ontoPolymerPhysicsII

Introduc0ontoPolymerPhysicsI

(Introduc0ontoPolymerChemistryII

Introduc0ontoPolymerChemistryI

AdvancedPolymerSynthesisI

28

１① １② １③ １④ ２① ２② ２③ ２④

SeminarinenergyscienceF1SeminarinenergyscienceS1 SeminarinenergyscienceS2 SeminarinenergyscienceF2ResearchSeminars

AdvancedPhysicalChemistry

Inorganic,analy-calchemistrysubjects

AdvancedSepara0onScience

BasicConceptsofInorganicChemistry

AdvancedOrganometallic

Chemistry

BasicConceptsofOrganicChemistry

AdvancedQuantumChemistry

BasicConceptsofPhysicalChemistry

AdvancedOrganicSynthesis

Cataly0cChemistryonSolidSurface

AdvancedBioorganicChemistry

GlobalEnvironmentalChemistry

AdvancedCourseinCrystal

StructureScience

Physicalchemistrysubjects

Organicchemistrysubjects

化学安全教育

LaboratoryTrainingofSynchrotronRadia0onScience

Interdisciplinaryscien0ficprinciplesofenergy1

Interdisciplinaryscien0ficprinciplesofenergy2

Interdisciplinaryprinciplesofenergydevices1

Interdisciplinaryprinciplesofenergydevices2 InterdisciplinaryEnergy

MaterialsScience1InterdisciplinaryEnergyMaterialsScience2

Red frame：Major courses Brown frame：Common subjects in chemistry department Black frame：Subjects of chemistry course (recommended)

AdvancedLectureon

CrystalStructureandCorrela0onwithProper0es

ofSolids

Op0calproper0esof

solids

Energysystemtheory Economyofenergysystem

Master’sThesisResearch

【DepartmentofChemistry,MajorofEnergyScienceandEngineering(Master’sprogram）】

MajorCourses(DepartmentofChemistry)

InterdisciplinaryScien0ficPrinciplesofEnergyCourses

Research-RelatedCourses Energyinnova0onco-crea0veproject

RequiredCourses Elec0veCourses

29

［Chemistry］

RequiredCourses Elec0veCourses

１① １② １③ １④ ２① ２② ２③ ２④

SeminarinenergyscienceF1SeminarinenergyscienceS1 SeminarinenergyscienceS2 SeminarinenergyscienceF2

Redframe:MajorCoursesBlackframe:Research-RelatedCourses

Characteriza0onofNanomaterials

EnvironmentalDegrada0onofMaterials

AdvancedMetalPhysics

PhysicalChemistryforHighTemperature

Processes-Smel0ngandRefiningProcesses- PhysicalChemistryforHigh

TemperatureProcesses-Oxida0onofMetals-

AdvancedMicrostructureDesignof

FerrousMaterials

TransportPhenomenaatHighTemperature

［Physics］

［Chemistry］

［Materials］

Metallurgy

QuantamSta0s0calMechanics

AdvancedSolidStatePhysics

ThemodynamicsforPhaseEquilibria

Deforma0onandStrengthofSolids

SoeMaterialsFunc0onalPhysics

AdvancedCourseinOrganicPolymerScience

［Physics］

［Property&Processing］SoeMaterialsPhysics

OrganicMaterialsDesign

AdvancedCourseinPolymerProcessing　A

AdvancedCourseinCompositeMaterials

SoeMaterialsFunc0on

OrganicOp0calMaterialsphysics

SoeMaterialsPhysicalChemistry

SoeMaterialsDesign

ChemistryofOrganicMaterials

SoeMaterialsChemistryII

MaterialsEngineeringandEcology

OrganicElectronicMaterialsPhysics

OrganicMaterialsFunc0onalDesign

SoeMaterialsFunc0onalChemistry

SoeMaterialsChemistryI

OrganicMaterials

EnergyConversionCeramicsMaterials

CrystalsScience

AdvancedCourseofDielectricandFerroelectric

Materials

QuantumPhysicsinOp0calResponseof

Materials

TopicsinProper0esofSemiconductors AdvancedCourseof

Magne0sm

AdvancedCourseofMaterialsOp0cs

AdvancedCourseofMaterialDevelopmentI

AdvancedCourseofMaterialDevelopmentII

Introduc0ontoIntellectualPropertySystem

Func-onalDevices

［Ma%erScience］

［TechnologyDevelopment&U-liza-on］

［StructureScience］

［ProcessScience&DeviceTechnology］

NuclearMaterialsScience

InorganicMaterials

【DepartmentofMaterialsScienceandEngineering,MajorofEnergyScienceandEngineering(Master’sprogram）】

Master’sThesisResearch

ResearchSeminars

MajorCourses(DepartmentofMaterialsScienceandEngineering)

InterdisciplinaryScien0ficPrinciplesofEnergyCoursesInterdisciplinaryscien0ficprinciplesofenergy1

Interdisciplinaryscien0ficprinciplesofenergy2

Interdisciplinaryprinciplesofenergydevices1

Interdisciplinaryprinciplesofenergydevices2 InterdisciplinaryEnergy

MaterialsScience1InterdisciplinaryEnergyMaterialsScience2

Energysystemtheory Economyofenergysystem

Research-RelatedCourses Energyinnova0onco-crea0veproject

AdvancedMicrostructureDesignofNon-ferrous

Materials

MicrostructureEvolu0onandDiffusioninMetals

AdvancedMicrostructureDesignofNon-ferrous

Materials

AdvancedCourseinPolymerProcessingB

ThermalProper0esofMaterials

PhysicalChemistryforHighTemperatureProcesses-

Thermodynamics-

AppliedDiffrac0onCrystallographyinMetals

andAlloys

AdvancedCourseofInstrumentalAnalysisfor

MaterialsAdvancedCourseofCeramicThinFilm

Technology

AdvancedCourseofDeforma0onand

FractureofEngineeringMaterials

30

【DepartmentofElectricalandElectronicEngineering,MajorofEnergyScienceandEngineering(Master’sprogram）】

１① １② １③ １④ ２① ２② ２③ ２④

SeminarinenergyscienceF1SeminarinenergyscienceS1 SeminarinenergyscienceS2 SeminarinenergyscienceF2

Common

VLSI Technology I

Fundamentals of Electronic Materials

Bipolar Transistors and Compound Semiconductor

Devices

Dielectric Property and Organic Devices

VLSI Technology II

Magne0smandSpintronicsIntroduc0onto

Photovoltaics

Advancedfunc0onal

electrondevices

Nano-StructureDevices

MixedSignalCircuits

Semiconductor Physics

Power,System

Device,Materials

TeraheltzDevicesandSystems

Advanced Electric Power Engineering

Plasma Engineering

ElectricPowerandMotorDriveSystemAnalysis

EnvironmentandElectricEnergy

PulsedPowerTechnology

AdvancedCourseofPowerElectronics

AdvancedPowerSemiconductorDevices

Magne0cLevita0onand

Magne0cSuspensionMechanical-to-electrical

energyconversion

Advanced Electromagnetic Waves

Wireless Communication Engineering

Optical Communication Systems

Utilization of Intelligent Information Resources and

Patents

ElectricalModelingandSimula0on

Master’sThesisResearch

ResearchSeminars

MajorCourses(DepartmentofElectricalandElectronicEngineering)

InterdisciplinaryScien0ficPrinciplesofEnergyCoursesInterdisciplinaryscien0ficprinciplesofenergy1

Interdisciplinaryscien0ficprinciplesofenergy2

Interdisciplinaryprinciplesofenergydevices1

Interdisciplinaryprinciplesofenergydevices2 InterdisciplinaryEnergy

MaterialsScience1InterdisciplinaryEnergyMaterialsScience2

Energysystemtheory Economyofenergysystem

Research-RelatedCourses Energyinnova0onco-crea0veproject

RequiredCourses Elec0veCourses

Redframe:MajorCoursesBlackframe:Research-RelatedCourses

31

１① １② １③ １④ ２① ２② ２③ ２④

MechanicsofCompositeMaterials

MechanicsofHighTemperatureMaterialsSolidDynamics

ThermodynamicsofNonequilibriumSystems

Computa0onalThermo-FluidDynamics

Proper0esofSolidMaterials

AdvancedThermal-FluidsMeasurement RarefiedGas

DynamicsPlasmaPhysics

FlyingObjectEngineering

MechatronicsDeviceandControl

AdvancedSoundandVibra0onMeasurement

AdvancedMechanicalElements

AdvancedCourseofActuatorEngineering

Ultra-precisionMeasurement (Mechanismand

ControlforUltra-precisionMo0on

Metalforming

AdvancedTribosystem

MechanicalProcessing

SpaceSystemsDesign

SpaceSystemsAnalysisA

SpaceSystemsandMissions

SpaceSystemsAnalysisB

PrecisionManufacturingProcesses

AdvancedCourseofMicroandNanoMachining

Advancedcourseofcombus0onphysics

SeminarinenergyscienceF1SeminarinenergyscienceS1 SeminarinenergyscienceS2 SeminarinenergyscienceF2

ThermoandFluidMechanics

MechanicalDynamics,Control,andMechatronics

Micro-machining

MechanicsofMaterial

SpaceEngineering

ProcessingandManufacturing

Advancedcourseofradia0ontransfer

Advancedcourseofturbulentflowand

control Advancedcourseofmul0scalethermal-

fluidsciences Leading edge energytechnology

ExperimentalModalAnalysisforStructural

Dynamics

Master’sThesisResearch

ResearchSeminars

【DepartmentofMechanicalEngineering,MajorofEnergyScienceandEngineering(Master’sprogram）】

MajorCourses(DepartmentofMechanicalEngineering)

InterdisciplinaryScien0ficPrinciplesofEnergyCoursesInterdisciplinaryscien0ficprinciplesofenergy1

Interdisciplinaryscien0ficprinciplesofenergy2

Interdisciplinaryprinciplesofenergydevices1

Interdisciplinaryprinciplesofenergydevices2 InterdisciplinaryEnergy

MaterialsScience1InterdisciplinaryEnergyMaterialsScience2

Energysystemtheory Economyofenergysystem

Research-RelatedCourses Energyinnova0onco-crea0veproject

RequiredCourses Elec0veCourses

Redframe:MajorCoursesBlackframe:Research-RelatedCourses

32

１① １② １③ １④ ２① ２② ２③ ２④

SeminarinenergyscienceF1SeminarinenergyscienceS1 SeminarinenergyscienceS2 SeminarinenergyscienceF2

MajorCourses(DepartmentofChemicalScienceandEngineering)

MajorCourses（ChemicalScienceandEngineering,Chemistry,MaterialsScienceandEngineering,ElectricalandElectronicEngineering,orMechanicalEngineering）

MajorCourses(DepartmentofChemistry)

DepartmentofMaterialsScienceandEngineering

MajorCourses(DepartmentofElectricalandElectronicEngineering)

MajorCourses(DepartmentofMechanicalEngineering)

ResearchSeminars

Master’sThesisResearch

InterdisciplinaryScien0ficPrinciplesofEnergyCoursesInterdisciplinaryscien0ficprinciplesofenergy1

Interdisciplinaryscien0ficprinciplesofenergy2

Interdisciplinaryprinciplesofenergydevices1

Interdisciplinaryprinciplesofenergydevices2 InterdisciplinaryEnergy

MaterialsScience1InterdisciplinaryEnergyMaterialsScience2

Energysystemtheory Economyofenergysystem

Research-RelatedCourses Energyinnova0onco-crea0veproject

【DepartmentofTransdisciplinaryScienceandEngineering,MajorofEnergyScienceandEngineering(Master’sprogram）】

RequiredCourses Elec0veCourses

33

DoctoralDisserta0onResearch

【CoreCoursesoftheGraduateMajorinEnergyScienceandEngineering（Doctor’sProgram）】

１① １② １③ １④ ２① ２② ２③ ２④ ３① ３② ３③ ３④

SeminarinenergyscienceS3 SeminarinenergyscienceF3 SeminarinenergyscienceS4 SeminarinenergyscienceF4 SeminarinenergyscienceS5 SeminarinenergyscienceF5

IndependentStudiesCourses1

Path-BreakingLiberalArtsCourses1

ALP Introduc0on ALP Prac0ceI(TeachingPrac0ce)

Humani0esandSocialSciencesCourses

CareerDevelopmentCourses

ResearchSeminars

Academic WritingA

Academic WritingB1

Interna0onalscien0ficpresenta0onA

Interna0onalscien0ficpresenta0onB

MajorCourses

Prac0calresearchinenergyscienceA

Prac0calresearchinenergyscienceB

RequiredCourses Elec0veCourses

IndependentStudiesCourses1

Path-BreakingLiberalArtsCourses1

34