List of Subjects for International Graduate Course Program
Ÿ Sustainable Engineering Program
1. Program Outline
Sustainable Engineering Program (SEP) aims to train ghighly
educated, internationalized engineersh having a wide spectrum of technical
knowledge from fundamentals to their applications. Degree recipients in this
program are expected to participate as leaders in international projects, such
as overseas deployments by Japanese companies and development projects by
international organizations, with creative and innovative manners in the
related fields. SEP consists of six special courses as fundamental disciplines
in Sustainable Engineering aiming at the sustainable society and development as
shown in the figure below. The student will be enrolled in a special course and
educated in Integrated Doctoral Education Program, in which they are expected
to study from Masterfs to Doctoral programs continuously for the both degrees.
2. Course Outlines and Faculty
Six special courses fall into two groups: One focuses on the
technology for infrastructure development, the other on the technology for
industrial development. Each course consists of several departments, which are
closely related to the objectives of the course. Course outlines as well as
departments and faculty members involved in the courses are given in order as
below.
Technology for
Infrastructure Development
2.1 Development and Environmental
Engineering Course
Construction, maintenance and renewal of various
infrastructures are of vital importance in every nation for developing all
types of industry and creating secure and firm build environments.
Infrastructure developments have been carried out as a national or an
international project under various environments, such as natural, social,
economical and human environments. Therefore the infrastructure development
harmonized with the environments is crucial to sustainable development of
society and industry. This course based on Civil and Environmental Engineering,
and International Development Engineering aims its mission to train creative
engineers and scientists. The graduates of this course are expected to play
pivotal roles in various projects, e.g., infrastructure development, resource
development and environment preservation projects, as a leading engineer or a
project manager.
Dept. of International Development
Engineering
Professors:
OTSUKI,
Nobuaki, D. Eng. Construction
Materials
HINODE,
Hirofumi, D. Eng. Inorganic
Materials and Properties, Catalyst and Chemical,
Process,
Chemical Engineering in General
TAKADA
Jun-ichi, D. Eng. Wireless
Communications, ICT and Development
MOCHIMARU,
Yoshihiro, D. Eng. Fluid
Dynamics, Thermal Engineering, Chemical Engineering
HIROSE,
Sachio, D. Eng. International
Student Education, Biochemical Engineering,
Diagnostic
Reagents, Polymer Engineering
YAMAGUCHI
Shinobu, Ph. D. Education
and IT, International Development and Cooperation,
Sustainable
Development of World Cultural Heritage
Associate
Professors:
ABE
Naoya, Ph. D. Environmental
Economics
HANAOKA
Shinya, D. Info. Sci. Transportation
Engineering, Project Management
KANDA,
Manabu, D. Eng. Environmental
Hydrology
YAMASHITA,
Yukihiko, D. Eng. Computer
Science, Intelligent Informatics
EGASHIRA,
Ryuichi, D. Eng. Separation
Engineering, Separation Process, Separation Operation
TAKAHASHI,
Kunio, D. Eng. Certification
System of Engineers, Sustainable Processes in
Joining,
Welding, Tiribology, Surface Science and Technology
PIPATPONGSA
Thirapong, D. Eng. Geotechnical
Engineering, Continuum Mechanics
Dept. of Civil and Environmental
Engineering
Professors:
MIKI,
Chitoshi, D. Eng. Bridge
Engineering & Structural Design
NIWA,
Junichiro, D. Eng. Structural
Concrete
IKEDA,
Shunsuke, D. Eng. Hydraulics
KUSAKABE,
Osamu, Ph. D. Soil
Mechanics & Geotechnical Engineering
KAWASHIMA,
Kazuhiko, D. Eng. Structural
& Earthquake Engineering
FUJII,
Satoshi, D. Eng. Transportation
and Infrastructure Planning
HIROSE,
Sohichi, D. Eng. Applied
Solid Mechanics
ISHIKAWA,
Tadaharu, D. Eng. Water
Environment
NADAOKA,
Kazuo, D. Eng. Coastal
Engineering
OHMACHI,
Tatsuo, D. Eng. Earthquake
Engineering
YAI,
Tetsuo, D. Eng. Transportation
Planning & Engineering
Associate
Professors:
TAKEMURA,
Jiro, D. Eng. Soil
Mechanics & Geo-environmental Engineering
WIJEYEWICKREMA,
C. Anil, Ph. D. Structural
Mechanics & Solid Mechanics
FUKUDA,
Daisuke Transportation
and Infrastructure Planning
ICHIMURA,
Tsuyoshi Computational
Earthquake Engineering
YAGI,
Hiroshi, D. Eng. Coastal
Engineering
MORIKAWA,
Hitoshi, D. Eng. Earthquake
Engineering
MUROMACHI,
Yasunori, D. Eng. Urban
Transportation Planning
NAKAMURA,
Takeshi, D. Eng. Numerical
Fluid Mechanics
TAKAHASHI, Akihiro,
D. Eng. @@@@Geotechnical
Engineering
2.2 Nuclear Engineering Course
Growing attention has been again placed on nuclear energy as
an ultimate measure for reduction of fossil fuel consumption and CO2
emission. Under the circumstances of global warming and the price hike of oil,
gas and coal, a number of countries have been considering the implementation of
nuclear power plants. Some
countries have initiated reconsideration on their denuclear policy. The key
factor of the nuclear energy development is the development of human
resources. Our original course of
international nuclear engineering has been established in1993. Since then, a number of students have
joined us from many different countries and graduated from our course. They are
actively contributing to the development of industries and technologies in
their own countries. This graduate
course provides with core curriculum for nuclear reactor engineering and fuel
cycle technologies and also covers extended nuclear energy, such as beam,
accelerator, plasma sciences, nuclear fusion, energy and environment, and
social relations.
Dept. of Nuclear Engineering
Professors:
NINOKATA, Hisashi, D. Eng. Nuclear
Reactor Engineering, Thermohydraulics and Safety
ARITOMI,
Masanori, D. Eng. Nuclear
Thermal Engineering
SEKIMOTO,
Hiroshi, Ph. D. Neutronics,
Nuclear Reactor Design, Fuel Cycle Systems
FUJII,
Yasuhiko, D. Eng. Nuclear
Fuel Chemistry, Separations Science, Ion Exchange,
Plasma
Chemistry, Isotope Separation
YANO,
Toyohiko, D. Eng. Nuclear
Reactor Materials, Radiation Damages, Ceramic Matrix
Composites
AOKI,
Takayuki, D. Sc. Large-scale
Computational Fluid Dynamics, HPC Grid
Application,
Computational Physics and Engineering, Global
Environmental,
Simulation, Computational Medicine
YOSHIZAWA,
Yoshio, D. Eng. Thermal
Engineering, Energy System, Combustion
SHIMADA,
Ryuichi, D. Eng. Fusion
Reactor Control, Plasma Engineering, Superconductivity,
New
Energy, Energy Storage
HATTORI,
Toshiyuki, D. Sc. Accelerator
Physics, Heavy Ion Inertial Fusion
SAITO,
Masaki, D. Eng. Innovative
Nuclear Energy Systems, Transmutation of Nuclear Wastes,
Accelerator-driven System, Nuclear Safety and Security
SUZUKI,
Masaaki, D. Eng. Nuclear
Chemical Engineering, Plasma Engineering, Numerical
Heat
and Mass Transfer
Associate
Professors:
TAKAHASHI,
Minoru, D. Eng. Fast
Reactor Engineering, Thermal Hydraulics, Nuclear Material,
Fusion
Reactor Blanket
IGASHIRA,
Masayuki, D. Eng. Neutron
Physics, Nuclear Transmutation, Nuclear Physics
IKEDA,
Yasuhisa, D. Eng. Actinide
Chemistry, Nuclear Fuel Reprocessing, NMR
Micro-imaging,
Green Chemistry (Supercritical Fluids, Ionic
Liquids),
Radioactive Waste Management
ONOE,
Jun, D. Sc. Nano-materials
Science, Nano-carbon, Single-molecule
Spectroscopy
KATO,
Yukitaka, D. Eng. Energy
Conversion, Chemical Heat Pump, Hydrogen Energy, Fuel
Cell,
Zero-emission Energy System
OBARA,
Toru, D. Eng. Reactor
Physics, Nuclear Reactor Design, Radioactive Waste
Treatment
OGURI,
Yoshiyuki, D. Eng. Heavy
Ion Inertial Fusion, Accelerator-based Environmental
Sciences
AKATSUKA,
Hiroshi, D. Eng. Plasma
Diagnostics, Plasma Spectroscopy, Laser Engineering,
Atomic
and Molecular Processes in Plasmas
IIO,
Shunji, D. Sc. Plasma
Physics, Fusion Engineering, Laser Diagnostics
MATSUMOTO,
Yoshihisa, PhD. Radiation
Biology, Molecular Biology and Biochemistry, Basic
Medicine
2.3 Infrastructure Metallic
Materials Course
Steel making industries and other metalworking industries
play important roles in advancing civilized society because they are producing
all kinds of infrastructure metallic materials to be used for other industries
such as construction, civil, mechanical, automobile and electronic industries.
Therefore, metallurgical engineering is one of the important basic
academic/engineering fields for industrialization of developing countries. This
graduate course is, thus, designed for those who want to be a pillar of
metalworking industries in developing countries. The course provides both
fundamental and applied metallurgy and covers all subjects of metallurgy based
on the following three categories: metal physics, metal chemistry, and
materials metallurgy.
Dept. of Metallurgy and Ceramics
Science (Metallurgy Group)
Professors:
TSURU,
Tooru, D. Eng. Electrochemistry,
Corrosion Engineering, Surface Treatment
MATSUO,
Takashi, D. Eng. Physical
Metallurgy of Iron and Steels, High Temperature
Deformation
MARUYAMA,
Toshio, D. Eng. Physical
Chemistry in Advanced Materials
SATO,
Tatsuo, D. Eng. Metallurgy
of Non-ferrous Metals and Alloys, Phase
Transformation
of Alloys, Solidification
SUSA,
Masahiro, D. Eng. Physical
Chemistry of Metals, Materials Metrology
NAKAMURA,
Yoshio, D. Eng. Applied
Diffraction Crystallography, Nano-Structured Materials
Associate
Professors:
NISHIKATA,
Atsushi, D. Eng. Metallurgical
Electrochemistry, High Temperature
Electrochemistry,
Corrosion
TAKEYAMA,
Masao, D. Eng. Physical
Metallurgy of Intermetallic and Ferrous Materials, Phase
Transformations
of Alloys, Deformation in Solid
KAWAMURA,
Kenichi, D. Eng. High
Temperature Physical Chemistry, Solid State Ionics
KOBAYASHI, Yoshinao, D. Eng. High
Temperature Thermodynamics, Metal Refining
SHI,
Ji, D. Eng. Physical
Properties of Metals, Magnetic Thin Films
Dept. of Chemistry and Materials
Science
Professor:
NAGATA,
Kazuhiro, D. Eng. High
Temperature Physical Chemistry, Processing of High
Temperature
Materials
Associate
Professor:
KANAZAWA,
Miyuki, D. Eng. Thermophysical
Properties of Materials, High Temperature
Process
Control
Dept. of Materials Science and
Engineering
Professors:
KATO,
Masaharu, D. Eng. Physical
and Mechanical Metallurgy
MISHIMA,
Yoshinao, Ph D, D. Eng. Physical
Metallurgy
KUMAI,
Shinji, D. Eng. Mechanical
Metallurgy, Fatigue, Joining and Solidification
ONAKA,
Susumu, D. Eng. Mechanical
Properties of Materials
Associate
Professors:
KAJIHARA,
Masanori, D. Eng. Thermodynamics
and Kinetics
KIMURA,
Yoshisato, D. Eng. Microstructure
Control and Characterization of Intermetallic
Alloys
Dept. of Innovative and Engineered
Materials
Associate
Professors:
FUJII,
Toshiyuki, D. Eng. Crystallography
of Microstructures
HOSODA,
Hideki, D. Eng. Materials
Design, Shape Memory Alloys, Intermetallic
Compounds
Technology for
Industrial Development
2.4 Mechanical and Production
Engineering Course
Mechanical and Production Engineering is a foundation of an
advanced industrial nation and a key technology for the industries such as
automobile, electrical and electronic products, precision instruments and
robotics. To learn and master the ability of planning, operation and management
through a research project related on the art and craft. Students will play an
important role in an international corporation and public organization.
Dept. of Mechanical Sciences and
Engineering
Professors:
YABE,
Takashi, D. Eng. Fluid
Science and Engineering
INOUE,
Takayoshi, D. Eng. Microscale
Thermal Engineering
IWATSUKI,
Nobuyuki, D. Eng. Human
Friendly Systems, Silent Engineering,
Laser
Interferometry
SUGIMOTO,
Koichi, D. Eng. Kinematics
HAGIWARA,
Ichiro, D. Eng. Design-based
Production Engineering
MURAKAMI,
Hiroya, D. Eng. Forming
Technology and Productivity Design
TOKURA,
Hitoshi, D. Eng. Surface
Engineering
KISHIMOTO
Kikuo, D. Eng. Solids
and Structures Engineering
TODOROKI,
Akira, D. Eng. Solids
and Structures Engineering
Associate
Professors:
OKAWA,
Seiji, D. Eng. Thermal
Science and Engineering
OSHIMA,
Shuzo, D. Eng. Fluid
Science and Engineering
OKADA,
Masafumi, D. Eng. Robotics,
Control Engineering
TAKAHARA,
Hiroki, D. Eng. Structural
Dynamics
TAKEDA,
Yukio, D. Eng. Mechanical
Systems Design
TAKAHASHI,
Hidetomo, D. Eng. Design-based
Production Mechanics
HIRATA,
Atsushi, D. Eng. Surface
Engineering
ADACHI,
Tadaharu, D. Eng. Materials
Science and Engineering
MIZUTANI,
Yoshihiro, D. Eng.
Structural Reliability Engineering
Dept. of Mechanical and Control
Engineering
Professors:
SAITO,
Yoshio, D. Eng. Intelligent
and Integrated Manufacturing
NAKAMURA,
Haruo, D. Eng. Fracture
Mechanics, Strength of Materials
YOSHINO,
Masahiko, D. Eng. Manufacturing
Systems Engineering
OKAZAKI,
Ken, D. Eng. Energy
Phenomena, Global Environment
SATOH,
Isao, D. Eng. Energy
Applications
KASHIWAGI,
Takao, D. Eng. Energy
and Environment Systems
INOU,
Norio, D. Eng. Biomechanics
HACHIYA,
Hiroyuki, D. Eng Ultrasonic
Measurements, Acoustic Imaging
KITAGAWA,
Ato, D. Eng. Instruments
for Control, Fluid Power Control
OKUTOMI,
Masatoshi, D. Eng. Computer
Vision, Image Processing
SAMPEI,
Mitsuji, D. Eng. Control
Theory
FUJITA,
Masayuki, D. Eng. Systems
and Control
HIRAI,
Shuichiro, D. Eng. Global
Environment Engineering
HANAMURA,
Katsunori, D. Eng. Environmental
Thermal Engineering
Associate
Professors:
TANAKA,
Tomohisa, D. Eng. Intelligent
and Integrated Manufacturing
INOUE,
Hirotsugu, D. Eng. Solid
Systems Engineering
FUSHINOBU,
Kazuyoshi, D. Eng. Energy
Phenomena
SAITO,
Takushi, D. Eng. Heat
Transfer, Material Processing
YAMAURA,
Hiroshi, D. Eng. Dynamics
and Control of Machinery
OHYAMA,
Shinji, D. Eng. Science
for Measurements
YAMAKITA,
Masaki, D. Eng. Instruments
for Control
TSUKAGOSHI,
Hideyuki, D. Eng. Fluid
Power Control, Rescue Robot
KURABAYASHI,
Daisuke, D. Eng. Motion
Planning, Multi Robot Systems
TSUSHIMA,
Shohji, D. Eng. Thermal
and Energy Engineering, Fuel Cell
Dept. of Mechanical and Aerospace
Engineering
Professors:
MIYAUCHI,
Toshio, D. Eng. Computational
Fluid Dynamics, Combustion,
Turbulence
OKUMA,
Masaaki, D. Eng. Structural
Dynamics, Acoustics, Optimum Design,
CAE
SUZUMURA,
Akio, D. Eng. Joining
Advanced Materials
KYOGOKU,
Keiji, D. Eng. Tribology,
Machine Elements
HIROSE,
Shigeo, D. Eng. Robotics,
Creative Design of Mechanical System
ODA,
Mitsushige, D. Eng. Space
Systems Engineering, Space Robot
Associate
Professors:
TANAHASHI,
Mamoru, D. Eng. Fluid
Dynamics, Heat and Mass Transfer,
Combustion
KOSAKA,
Hidenori, D. Eng. Thermodynamics,
Fluid Dynamics, Combustion
HORIUTI,
Kiyosi, D. Eng. Fluid
Physics, Turbulence
MATUNAGA,
Saburo, D. Eng. Space
Systems Engineering, Space Robotics, Small Satellite
Small
Satellite
KAJIWARA,
Itsuro, D. Eng. Multidisciplinary
Design Optimization, Smart
Structure,
Motion and Vibration Control
YAMAZAKI,
Takahisa, D. Eng. Materials
for Space Use, Advanced Joining and
Surface
Coating
SAITO,
Shigeki, D. Eng. Micromechanics,
Micro Robotics
FUKUSHIMA,
E, Fumihiko, D. Eng. Robotics,
Creative Design of Mechanical System
2.5 Information and Communication
Technology Course
Information and communications technology consists of a broad
spectrum of technologies and is one of the most important social
infrastructures supporting the industry, economy, and culture. This course is
organized by the departments of electrical and electronic engineering, physical
electronics, and communications and integrated systems, offering comprehensive
research and education covering software and hardware technology in this field.
The course covers topics in information and communications technology also
including signal processing, electromagnetic waves, integrated circuits, and
electron devices. We ensure that graduate students pursue challenging and
valuable research on the course for professional education in the class and in
the laboratories to become world-class leaders who can support this field.
All students in the course will belong to one of the
departments mentioned above and are required to take classes prepared for the
information and communications technology course.
Dept. of Electrical and Electronic
Engineering
Professors:
AKAGI,
Hirofumi, D. Eng. Power
Electronics, Electric Machinery
ANDO,
Makoto, D. Eng. Antennas,
Millimeter wave communication/
sensing systems,
ARAKI,
Kiyomichi, D. Eng. Space-time
Coding, Wireless Communications,
Cryptography,
Software
Defined Radio, RF Circuits
MIZUMOTO,
Tetsuya, D. Eng. Lightwave
Circuits, Integrated Optics
Associate
Professors:
HIROKAWA,
Jiro, D. Eng. Antennas,
Electromagnetic Wave Theory
SAKAGUCHI, Kei, Ph. D. MIMO
Wireless Communications
SANDHU, Adarsh, Ph. D. Nanoelectronics,
Magnetic
Biomedical Diagnostics,
Semiconductor
Engineering, Scientific Writing
Dept. of Physical Electronics
Professors:
IWAMOTO,
Mitsumasa, D. Eng. Electronic
Materials, Molecular Electronics,
Organic
Materials Electronics
KONAGAI,
Makoto, D. Eng. Semiconductors
MATSUZAWA,
Akira, D. Eng. Integrated
Circuits, Mixed Signal LSI Design
ODA,
Shunri, D. Eng. Quantum
Nano Devices, Semiconductor Devices
Associate
Professors:
MAJIMA,
Yutaka, D.Eng. Molecular
Devices, Organic Semiconductors
NAKAGAWA,
Shigeki, D.Eng.
Information storage devices, Spintronics,
Magnetic materials
OKADA,
Ken-ichi, D. Inf. Wireless
Circuit Design
UCHIDA, Ken, D.
Eng. @@ @@Nanoelectronics,
Advanced CMOS Devices
@@ NAKAMOTO, Takamichi, D. Eng. @@ Sensing System, Human Interface, LSI Design
Dept. of Communications and
Integrated Systems
Professors:
KUNIEDA,
Hiroaki, D. Eng. VLSI
Design Micro-architecture, VLSI Signal
Processing
NISHIHARA,
Akinori, D. Eng. Digital
Filters, Signal Processing, Educational
Technology
SAKANIWA,
Kohichi, D. Eng. Communication
Theory, Coding Theory, Digital
Signal
Processing
SUZUKI,
Hiroshi, D. Eng. Mobile
Communications, Adaptive Signal
@@@@@@@@@@@ Processing,
Radio LAN Simulator with Multi-FPGA
TAKAGI,
Shigetaka, D. Eng. Integrated
Circuits, Circuit Theory
UENO,
Shuichi, D. Eng. Theory
of Parallel, VLSI and Quantum
Computation
UYEMATSU,
Tomohiko, D. Eng. Information
Theory, Coding Theory
YASHIMA,
Yoshiyuki (Visiting), D. Eng. Video
Compression Technology, Video Signal Processing
Associate
Professors:
FUKAWA,
Kazuhiko, D. Eng. Mobile
Communications, Signal Processing,
Adaptive
Filter Theory
ISSHIKI,
Tsuyoshi, Ph. D. System-LSI
Design Methodology, Reconfigurable
Systems
MATSUMOTO,
Ryutaroh, Ph. D. Quantum
Information Theory, Coding Theory
OGATA,
Wakaha, D. Eng. Information
Security, Cryptography
TAKAHASHI,
Atsushi, D. Eng. VLSI
Physical Design
YAMADA,
Isao, D. Eng. Signal
Processing, Communication Theory,
Optimization
Theory
YAMAOKA,
Katsunori, D. Eng. Information
and Communication Network
Lecturer:
IIDA,
Katsuyoshi, D. Computer Science Network
Systems Engineering, Performance
and
Systems Engineering Analysis
2.6 Advanced Materials and Chemicals
Processing Course
The aim of this course is to cultivate scientists and
engineers specializing in nanotechnology, advanced materials science and
advanced chemical processing technology, disciplines which are at the core of
sustainable development. The interactive and intensive curriculum, aimed at
putting knowledge to work on an applicable level, is prepared by top-level
departments, world-acclaimed in the field of ceramics science, organic and
polymeric materials and chemical engineering. Through the course work, students
are expected to become highly educated scientists and engineers possessing
advanced specialized knowledge and state-of-the-art professional skills.
Dept. of Metallurgy and Ceramics
Science (Ceramics Group)
Professors:
OKADA,
Kiyoshi, D. Eng. Environmental
Ceramics, Soft Chemical Process, Mineralogical Science
YANO,
Toyohiko, D. Eng. Processing
and Characterization of Engineered Ceramics,
Ceramic
Matrix Composites, Nuclear Reactor Materials
Associate
Professor:
NAKAJIMA,
Akira, Ph. D. Environmental
Ceramics, Surface Functional Materials
Dept. of Organic and Polymeric
Materials
(Chemistry
Group)
Professors:
HIRAO,
Akira, D. Eng. Polymer
Synthesis, Living Polymerization
TOSHIKAZU,
Takata, D. Sci. Polymer
Synthesis, Organic Chemistry, Supramolecular
Chemistry
Associate Professor:
Or
(Materials
Group)
Professors:
KAKIMOTO,
Masa-aki, D. Sc. Polymer
Synthesis, Polymer Thin Films
TAKEZOE,
Hideo, D. Sc. Optical
and Electrical Properties of Organic Materials
OKUI,
Norimasa, D. Eng. Organic
Thin Films, Physical Properties of Polymers
TANIOKA,
Akihiko, D. Eng. Physical
Chemistry of Organic Materials
HASHIMOTO,
Toshimasa, D. Eng. Polymer
Processing, Thermal Properties of Polymers
KIKUTANI,
Takeshi, D. Eng. Fiber
and Polymer Processing, Physical Properties of Polymers
TEZUKA,
Yasuyuki, D. Sc. Synthetic
Polymer Chemistry
SUMITA,
Masao, D. Eng. Solid
Structure and Physical Properties of Organic Materials,
Polymer Composites
MORI,
Takehiko, D. Sc. Physical
Chemistry of Organic Materials
Associate
Professors:
ISHIKAWA,
Ken, D. Eng. Optical
and Electrical Properties of Organic Materials
OUGIZAWA,
Toshiaki, D. Eng. Physical
Chemistry of Polymeric Materials
SHIOYA,
Masatoshi, D. Eng. Polymer
Composites, Mechanical Properties, Carbon Materials
VACHA,
Martin, D.Sc. Optical
Properties of Organic Materials
ASAI,
Shigeo, D. Eng. Physical
Properties of Organic Materials, Polymer Composites
Dept. of Chemical Engineering
Professors:
MASUKO,
Masabumi, D. Eng. Tribology,
Applied Surface Chemistry, Physical Chemistry
of Petroleum Products
KURODA,
Chiaki, D. Eng. Process
System, Intelligent System, Flow System
OHTAGUCHI,
Kazuhisa, D. Eng. Process
Design, Biochemical Reaction Engineering
SUZUKI,
Masaaki, D. Eng. Plasma
Engineering, Nuclear Chemical Engineering
Associate
Professors:
TANIGUCHI,
Izumi, D. Eng. Aerosol
Science and Technology, Fine Powder Engineering
FUCHINO,
Tetsuo, D. Eng. Process
Systems Engineering, Product Management
AIDA,
Takashi, D. Eng. Catalytic
Reaction Engineering, Catalysis
KUBOUCHI,
Masatoshi, D. Eng. Chemical
Plant Materials, Composite Materials, Material
Science
SEKIGUCHI,
Hidetoshi, D. Eng. Plasma
Processing, Thermo-chemical Engineering
KOSUGE,
Hitoshi, D. Eng. Separation
Engineering
YOSHIKAWA,
Shiro, D. Eng. Fluid
Dynamics, Transport Phenomena
3. Guide to Study in Sustainable
Engineering Program
Sustainable Engineering Program (SEP) has been designed in
the scheme of eIntegrated Doctoral Education Programf in which the
Masterfs program is combined with the Doctoral program. Thus, all students in
SEP, including Masterfs degree recipients at other universities, must start
with the Masterfs program and are to study for both Masterfs and Doctoral
degrees.
To acquire the degrees, students in SEP must satisfy several
requirements as follows.
yMasterfs degreez
For a Masterfs degree a student must take 30 credits or more
and meet other requirements as follows:
(1) Credits
a. 16
credits or more must be acquired from the subjects provided by the special
course which she/he enrolls in.
b. 4
credits or more must be acquired from the subjects provided by other courses or
departments, common subjects in SEP or institute-wide subjects, such as
international communication subjects and Japanese cultures.
c.
The seminar must be acquired in each term. Note that the required number of
credits about the seminar might be different depending on the special course.
(2) Thesis
The student must
complete a special research, submit a thesis for the degree and take the final
examination given after the submission of her/his thesis for the qualification.
The students qualified by the examination committee can go
onto the Doctoral program with some formalities.
yDoctoral degreez
For a Doctoral degree a doctoral candidate must satisfy the
following requirements:
(1) Seminar
in each term and Off-Campus Project must be taken.
(2) Beside
the requirement (1), 26 credits or more must be acquired from the subjects
provided in the Masterfs and Doctoral programs.
(3) The
candidate must complete and submit a thesis for the degree, and take the final
examination and evaluation of his/her thesis.
The candidate who satisfies the above requirements and passes
the final examination is awarded a Doctoral degree.
The minimum period of study is three years in total, which
include both the Masterfs and Doctoral program for the both degrees. Note that
the above requirements are minimal and some additional requirements may be
conditioned depending on the special course. All students are strongly advised
to consult with their own supervisors about the study plan.
4. Tables of Course Subjects
All lectures offered in this program are given in English.
The students can learn the following subjects: 1) specialized subjects in the
enrolled course, 2) subjects in the other special courses relevant to the
specialty, and 3) common subjects in SEP. Beside the above subjects, the
students are required to take part in Off-Campus Project, i.e., internship program
primarily in domestic companies. The course subjects provided by SEP are given
in the following tables. Please note that the subjects might be subject to
change.
4.0 Common subjects in SEP
|
Course title |
Category* |
|
Sustainable
Development and Integrated Management Approach |
B/I |
|
Principles of
International Co-existence |
B/I |
|
Managerial
Perspective for Sustainable Engineering |
B/I |
|
Sustainable
Engineering Technology |
B/I |
|
Special Lecture "Science of Materials" |
B/I |
* B: Basic, A: Applied, I: Interdisciplinary
4.1 Development and Environmental
Engineering (DEE) Course
|
Course title |
Category* |
|
Mathematical Science
in Development Engineering |
B |
|
International
Development Projects with Case Method |
B/I |
|
Environmental
Engineering for Development |
B/I |
|
International Engineering
Communication A |
I |
|
International
Engineering Communication B |
I |
|
Advanced Technical
Communication Skills I |
B/I |
|
Advanced Technical
Communication Skills II |
B/I |
|
Advanced Course on
Coastal Environments |
A |
|
Regional Atmospheric
Environment |
A |
|
Advanced Course of
Fluid Mechanics |
B |
|
Geo-Environmental
Engineering |
B |
|
Physical Modelling in
Geotechnics |
A |
|
Advanced Mathematical
Method for Infrastructure and Transportation Planning |
B |
|
Advanced
Transportation Planning and Traffic Engineering |
B |
|
Theory of Regional
Planning Process |
A |
|
Stability Analysis in
Geotechnical Engineering |
A |
|
Advanced Geotechnical
Engineering |
B |
|
Mechanics of
Geomaterials |
B |
|
Seismic Design of
Urban Infrastructures |
B |
|
Seismic Response
Modification of Urban Infrastructures |
A |
|
Advanced Concrete
Technology |
B |
|
Mechanics of
Structural Concrete |
B |
|
Durability and
maintenance of Construction Materials |
A |
|
Fracture Control
Design of Steel Structures |
A |
|
Analysis of Vibration
and Elastic Wave |
B |
|
Retrofit Engineering
for Urban Infrastructures |
A |
|
Introduction to Solid
Mechanics |
B/I |
|
Advanced Course on
Elasticity Theory |
B/I |
|
Principles of
Construction Management |
B/I |
|
Civil Engineering
Analysis |
B |
|
Advanced
Computational Method in Civil Engineering |
B |
|
Rural
Telecommunications |
A |
|
Basic Theories for
Information Processing |
A |
|
New Trends in
Numerical Analysis |
A |
|
Welding and Joining
Technology |
A |
|
Perspective
Understanding of Various Kinds of Material |
A |
|
Applied Economics for
Engineers |
B/I |
|
Project Evaluation
for Sustainable Infrastructure |
A/I |
|
Advanced Topics in
Civil Engineering I |
B |
|
Advanced Topics in
Civil Engineering II |
A |
|
Field Work in
Engineering for Sustainable Development A |
|
|
Field Work in
Engineering for Sustainable Development B |
|
|
Development and
Environmental Engineering Off-Campus Project I or II |
Required |
|
Special Experiments
of Development and Environmental Engineering I, II, III, IV |
Required |
|
Seminar of
Development and Environmental Engineering I, II, III, IV, V, VI, VII, VIII,
IX, X |
Required |
* B: Basic, A: Applied, I: Interdisciplinary
4.2 Nuclear Engineering Course
|
Course title |
Category* |
|
Basic Nuclear Physics |
B |
|
Nuclear Reactor
Theory |
B |
|
Nuclear Chemistry and
Radiation Science |
B |
|
Nuclear Energy
Systems |
B |
|
Nuclear Reactor
Safety |
B |
|
Nuclear Reactor
Design and Engineering |
A |
|
Nuclear Materials
Science |
A |
|
Reactor Chemistry and
Chemical Engineering |
A |
|
Reactor Thermal
Hydrodynamics |
A |
|
Accelerators in
Applied Research and Technology |
A |
|
Energy Systems and
Environment |
I |
|
Plasma Science |
I |
|
Computational Fluid
Dynamics |
I |
|
Experiments in Nuclear
Engineering I |
B |
|
Nuclear Engineering
Off-Campus Project I, II |
B |
|
Seminar in Nuclear
Engineering I, II, III, IV, V, VI, VII, VIII, IX, X |
B/A |
* B: Basic, A: Applied, I: Interdisciplinary
4.3 Infrastructure Metallic
Materials Course
|
Course title |
Category* |
|
Applied Diffraction
Crystallography in Metals and Alloys |
B |
|
Crystallography for
Microstructural Characterization |
B |
|
Advanced Metal
Physics |
B |
|
Deformation Mechanics
of Solid Materials |
B |
|
Thermodynamics for
Metallurgists |
B |
|
Physical Chemistry of
Melts |
B |
|
Electrochemistry of
Metals |
B |
|
Solid State Chemistry
in Metal Oxides |
B |
|
Transport Phenomena
of Metals and Alloys |
B |
|
High Temperature
Strength of Metals and Alloys |
A |
|
Phase Transformations
in Metals and Alloys |
A |
|
Microstructures of
Metals and Alloys |
A |
|
Characteristics and
Applications of Intermetallic Alloys |
A |
|
Diffusion in Alloys |
A |
|
Alloy Phase Diagrams |
A |
|
Advanced Ferrous and
Non-ferrous Materials |
A |
|
Science and
Engineering of Solidification |
A |
|
Environmental
Degradation of Materials |
I |
|
Non-equilibrium Thermodynamics
for Materials Science |
I |
|
Advanced
Metallurgical Engineering Laboratory |
B |
|
Materials Off-Campus
Project I, II |
Required |
|
Seminar in Materials
Science and Technology I-X |
Required |
* B: Basic, A: Applied, I: Interdisciplinary
4.4 Mechanical and Production
Engineering Course
|
Course title |
Category* |
|
Robot Creation |
A |
|
Advanced Course of
Mechanical Vibration |
B |
|
Advanced Course on
Applied Energy Engineering |
A |
|
Advanced Course on
Energy Physics |
B |
|
Intensive Thermal
Engineering |
B |
|
Thermal Engineering
in Environmental Problems |
A |
|
Advanced Course on
Basic Phenomenon of Liquid/Solid Phase Change |
B |
|
Theory and Practice
on Analysis and Design of Linear Control Systems |
B |
|
Advanced Course of
Mechanics of Materials |
B |
|
Advanced Course
of Mechanics of Fatigue and Fracture of Materials |
A |
|
Linear Fracture
Mechanics |
B |
|
Special Lecture on
Strength of Materials A |
A |
|
Special Lecture on
Strength of Materials B |
A |
|
Special Lecture on
Strength of Materials C |
A |
|
Special Lecture on
Strength of Materials D |
A |
|
Intelligent Control |
I |
|
Computer Vision |
B |
|
Advanced Course of
Fluid Power Robotics |
A |
|
Intelligent and
Integrated Manufacturing |
A |
|
Advanced Course of
Biomechanics |
A |
|
Special Lecture on
Mechano-Infra Engineering A |
I |
|
Special Lecture on
Mechano-Infra Engineering B |
I |
|
Special Lecture on
Mechano-Infra Engineering C |
I |
|
Special Lecture on
Mechano-Infra Engineering D |
I |
|
Automotive Structural
System Engineering (TAIST) |
A |
|
Automotive Comfort
Mechanics Engineering (TAIST) |
A |
|
Advanced Production
Engineering (TAIST) |
A |
|
Combustion Engineering
(TAIST) |
A |
|
Advanced Internal
Combustion Engine Engineering and Future Power Train (TAIST) |
A |
|
Basics of Automotive
Design (TAIST) |
A |
|
Practice of
Automotive Design (TAIST) |
A |
|
System Project
Research A |
I |
|
System Project
Research B |
I |
|
Seminar in Mechanical
and Production Engineering A |
A |
|
Seminar in Mechanical
and Production Engineering B |
A |
|
Seminar in Mechanical
and Production Engineering C |
A |
|
Seminar in Mechanical
and Production Engineering D |
A |
|
Mechanical and
Production Engineering Off-Campus Project I |
Required |
|
Mechanical and
Production Engineering Off-Campus Project II |
Required |
* B: Basic, A: Applied, I: Interdisciplinary
4.5 Information and Communication
Technology Course
|
Course title |
Category* |
|
Advanced
Electromagnetic Waves |
B |
|
Wireless
Communication Engineering I |
B |
|
Guided Wave Circuit
Theory |
B |
|
Electric Power System
Analysis |
A |
|
Introduction to
Photovoltaics |
A |
|
Advanced Electron
Devices |
B |
|
Mixed Signal Systems
and Integrated Circuits |
B |
|
Electronic Materials A |
B |
|
Electronic Materials B |
B |
|
Electronic Materials D |
B |
|
Physics and
Engineering of CMOS Devices |
B |
|
Topics on
Communication Systems Engineering |
A |
|
VLSI Design
Methodologies |
B |
|
Advanced Signal
Processing |
B |
|
Quantum Information
Processing |
A |
|
VLSI System Design |
B |
|
Advanced Coding
Theory |
B |
|
Speech Information
Processing |
A |
|
Rural
Telecommunications |
I |
|
Information and
Communication Technology Off-Campus Project I or II |
Required |
|
Special Experiments I
- II on Electrical and Electronic Engineering |
Required |
|
Seminar I - X on
Electrical and Electronic Engineering |
Required |
|
Special Lecture I -
VI on Electrical and Electronic Engineering |
A |
|
Special Experiments
I- II on Physical Electronics |
Required |
|
Seminar I - X on
Physical Electronics |
Required |
* B: Basic, A: Applied, I: Interdisciplinary
4.6 Advanced Materials and
Chemicals Processing Course
|
Course title |
Category* |
|
Advanced Separation
Operation |
B |
|
Transport Phenomena
and Operation for Advanced Materials and Chemicals Processing |
B |
|
Fine Particle
Engineering |
B |
|
Chemical Equipment
Design and Materials |
B |
|
Chemical Engineering
for Advanced Materials and Chemicals Processing I |
B |
|
Chemical Engineering
for Advanced Materials and Chemicals Processing II |
B |
|
Advanced Course in
Surface Properties of Organic Materials |
B |
|
Advanced Course in
Organic Materials for Photonics I |
B |
|
Advanced Course in
Organic Materials for Photonics II |
B |
|
Advanced Course in
Organic and Soft Materials Chemistry |
B |
|
Advanced Course in
Wettability Control of Solid Surface |
B |
|
Nuclear Materials
Science |
B |
|
Advanced Chemical
Reaction Engineering |
A |
|
Catalytic Process and
Engineering |
A |
|
Plasma and High
Temperature Processing |
A |
|
Advanced Course in
Physical Properties of Organic Materials |
A |
|
Advanced Course of
Organic Materials Design and Characterization |
A |
|
Advanced Course of
Polymer Chemistry |
A |
|
Advanced Course in
Environmental Aspects and Porous Materials |
A |
|
Nanoscale physics for materials science |
A |
|
Methodologies for
Nanomaterials Characterization |
A |
|
Life Cycle
Engineering |
I |
|
Practical Aspect for
Legal Agreement on Technical Issues |
I |
|
Topics in Advanced Organic,
Polymeric and Soft Materials |
I |
|
Topics in Advanced
Materials and Chemicals Processing I |
I |
|
Topics in Advanced
Materials and Chemicals Processing II |
I |
|
Chemical Engineering
Off-Campus Project I,II |
Required |
|
Materials Science and
Technology Off-Campus Project I,II |
Required |
|
Organic and Polymeric
Materials Off-Campus Project I,II |
Required |
|
Seminar in Chemical
Engineering I-X |
Required |
|
Seminar in Materials
Science and Technology I-X |
Required |
|
Seminar in Organic
and Polymeric Materials I-X |
Required |
* B: Basic, A: Applied, I: Interdisciplinary
5. Syllabus of Course Subjects
5.0 Common subjects in SEP
Sustainable Development and
Integrated Management Approach
Autumn Semester (1-1-0)
Prof. Jun-ichi TAKADA, and Prof. Shinobu YAMAGUCHI
[Aims]
This course aims at introducing various approaches to
sustainable development. The first half of the course looks at major theories
of international development and how they are applied in practical situations.
The latter part will take a close look at on-going development projects in
selected countries with implication of role of engineering (and engineers). The
students are expected to participate in discussion and analyze the project from
engineering point of view within the context of gSustainable Developmenth Then
the course will be followed by the field trip to the development project site,
possibly for conducting feasibility studies. The students are responsible to
prepare, to contribute, and to express own opinions and ideas. This means, the
studentsf participation in classroom makes a difference.
[Outline]
1. Introduction
to the course
2. Lecture/Discussion:
Development vs. Sustainable Development
3. Lecture/Discussion: Agenda
21, Capacity 21
4. Lecture/Discussion:
Feasibility Study as a Tool of Sustainable development
5. Group Presentation:
Sustainable Development
6. Group Presentation:
Sustainable Development
7. Introduction to development
project (1):
gUN
Human Security Funds (UNHSF) project gRehabilitation of Boarding Schools and
Provision of Refresher Training Course for Headmasters and Teachers in the Dzud
affected Gobi Desert Provinces in Mongoliah
8. In-class Group Exercises
9. Introduction to development
project (2):
gApplication
of technology to development of the World Heritage site in Lao PDRh
10. In-class
Group Exercises
11. Group
Presentation: Mongolian Team
12. Group
Presentation: Lao PDR Team
Principles of International
Co-existence
Spring Semester (2-0-0) (Odd Years)
Prof. Sachio HIROSE
[Aims]
Engineers sometimes encounter difficult ethical problems In
order to co-exist with others, we should know about ourselves as well as
others. In this lecture, we look
into the relationship between others and us in the different levels of
individual, races, corporations and nations.
[Outline]
1. Introduction
2. Relationship between Korea
and Japan
3. Relationship between China
and Japan
4. Humanitarian mind
5. Religion in the U.S.
6. Religion in the Mideast
7. International enterprise
8. Examples of establishing
corporation in foreign countries (1)
9. Examples of establishing
corporation in foreign countries (2)
10. Examples
of establishing corporation in foreign countries (3)
11. Collaboration
at the international field
12. Discussion
13. Summary
Managerial
Perspective for Sustainable Engineering
Autumn Semester (2-0-0)
Prof.Kumiko YOKOI (as the main coordinator); Several guest
lecturers will be invited from outside
[Aims and Scopes]
This lecture is intended to facilitate the graduate students
of engineering to have managerial perspectives, in order to make the best use
of the engineering research and study. Graduate students will broaden the
perspectives and have the deep insights, because guest lecturers with different
views and positions will be invited to the classroom. In the class, the basic
knowledge and concepts in business and management will be also mentioned.
[Outline]
1. Introduction - why "managerial
perspective?"
2. Managerial implication of accounting
3. Strategic use of intellectual property
4. IT and management
5. Venture capital and "university-corporate
relation"
6. Managerial insights for greenhouse gas
emissions (1)
7. Business strategy and technology
8. Managerial insights for greenhouse gas
emissions (2)
9. Japanese companies are not governed by
the shareholders?
10. Human capital and the metropolitan Tokyo
11. Case study - discussion
12. Good or bad? Financial engineering
13. Managerial insights for greenhouse gas
emissions (3)
14. Summary
[Evaluation]
Students are required to submit a
short report after each lecture. Active participation in discussion or raising
questions will be positively considered.
[Text] Class notes will be provided
Sustainable Engineering Technology
Autumn Semester (1-1-0)
Coordinators of SEP and invited
lectures
[Aims and scopes]
Sustainable Development has been
secured by a various technologies. In this course, leading engineers and
researchers will give lectures on a specific area which is crucial for
sustainable development, such as, energy and environment, material production,
and information technology. In
addition to the lectures, the students will investigate the relation of their
specialty to the specific area by various ways, including site visits, and give
presentations on the investigation to share the knowledge with the students of
different specialty in a seminar. Through lectures and seminars with
the discussions by the students of different disciplines, this course aims to
train the students as ghighly educated, internationalized engineersh having a
wide spectrum of technical knowledge from basics to their applications
Special Lecture "Science of
Materials"
Autumn Semester (1-0-0)
Dr. Kotobu Nagai, Dr. Shiro Torizuka, Dr. Toshiyuki Koyama,
Dr. Akihiro Kikuchi
[Aims]
This course aims at introducing various materials in the
aspect of science through many topics drawing attentions in developing high
performance materials in the field of infrastructure, energy and environmental
conscious materials, combined with computational simulation. The following four
topics related to innovative materials and creation process are selected to
provide fundamental knowledge and broad interest in the science of materials.
1. Overviews of environmental and energy materials
2. Cutting edge of ultra steels with high
performance
3. Thermodynamics and kinetics for computational
materials design
4. Evolution of superconductive materials
5.1 Development and Environmental
Engineering (DEE) Course
Mathematical Science in Development
Engineering
Spring Semester (2-0-0) (Even Years)
Assoc. Prof. Yukihiko YAMASHITA
[Aims]
The objective of this course is to provide basic mathematics
for understanding control theory in mechanical production and various phenomena
in the international development engineering. The linear algebra, functional
analysis, and the optimization theory, which are very important bases of
mathematics, are explained.
[Outline]
1. Introduction
2. Linear algebra
3. Hilbert space
4. Least square estimation
5. Dual space
6. Linear operator
7. Adjoint operator
8. Optimization of functional
International Development Projects
with Case Method
Spring Semester (0-2-0)
Prof. Jun-ichi TAKADA and Prof. Shinobu YAMAGUCHI
[Aims]
This course aims at introducing practical approaches to
development projects. Traditional teaching in the classroom based on lectures
and exams, often do not address the need for practical, problem-solving skills.
The important and crucial ability for effective project management is the
ability to think, analyze, discuss, and develop solutions to problems as
professionals may encounter in the field. The case method is an effective
approach to strengthening these skills.
[Outline]
1. Introduction to the course
2. Lecture/Discussion:
Development & Human Development Indicator
3. Case Method 1: gPolio
Immunization Policy in Lang-Tang Provinceh
4. Lecture/Discussion: Rural
Development and Participation Approach
5. Case Method 2: gInternational
Collaboration in Developing Countriesh
6. Lecture/Discussion: Rural
Development Participation
7. Paper Writing
8. Case Method 3: gRun before
You Get Shot down?h
9. Lecture/Discussion: Risk
Management of Technological Change
10. Case
Method 4: gAcademic Cooperation Program with Thailandh
11. Lecture/Discussion:
Community Development
12. Case
Method 5: gWhat did I do wrong?h
13. Group
Presentation/Paper Writing
Environmental Engineering for
Development
Spring Semester (2-0-0) (Odd Years)
Prof. Hirofumi HINODE, Prof. Masakazu SASAKI and Assoc. Prof.
Naoya ABE
[Aims]
This lecture outlines international environmental problems
from the engineering side.
[Outline]
1. Introduction
2. Population Growth
3. Air Pollution
1) Aid Rain
2) Ozone Depletion
3) Global Warming
4. Marine Pest
5. Deforestation and
Desertification
6. Energy Problem
1) Fossil Fuel Energy and New
Energy
2) Energy Saving
7. Waste Management
1) Recycling
2) Eco-business
International Engineering
Communication A
Intensive course in September (2-0-0)
Prof. Sachio HIROSE et al.
[Aims]
The subject explores principles and skills of human
communication in international English and in the context of international
engineering research and practice.
[Outline]
Monday/
Orientation and Introduction, Interpersonal and Group Communication, Cultural
Issues
Tuesday/
Thinking and Reasoning, Student Presentation, Speaking and Listening
Wednesday/
Speaking and Listening Workshop-Student Presentation/ Speaking and Listening
Workshop-Student Presentation, Technical Writing
Thursday/
International Writing, Writing Activity, Collaborative Writing and Teamwork
Friday/ Editing
and Revising, Writing Activity, Writing Activity
Saturday/
Professional Presentations and Discussion, Professional Presentations and
Discussion, Farewell Party
International Engineering
Communication B
Intensive course in September (2-0-0)
Prof. Sachio HIROSE et al.
[Aims]
The subject adopts a holistic view of project management
emphasizing the socio-cultural and communication aspects of project management.
The perspective of stakeholders, particularly the project manager will be
considered.
[Outline]
Monday/
Introduction and Overview of Course, Introduction to Communication Skills for
Project Managers, Organizational Strategy, Structure and Culture
Tuesday/
Individual Oral Presentations, Technology and Culture, Managing Project Time
and Cost
Wednesday/
Individual Oral Presentations, Developing a Project Plan, Managing Project Risk
and Quality
Thursday/
Individual Oral Presentations, Scheduling Resources, Reducing Project Duration
Friday/
Individual Oral Presentations, Leadership, Teams and Inter-Organizational
Relationships, Conflict Resolution in the Workplace
Saturday/ Group
Oral Presentations/ Group Oral Presentations/ Farewell Party
Advanced Technical Communication
Skills I
Spring Semester (1-3-0) (Every Year)
Prof. Koji TOKIMATSU and Prof. Osamu KUSAKABE
[Aims and Scope]
This course is designed to improve technical communication
skills.
[Outline]
1. Engineering Communication
2. Presentation Skills
3. Impromptu Speaking
4. Listening to Others
5. Managing and Leading
6. Stress Management
7. Creative Thinking
8. Steps to Good Writing
9. Mind Mapping
10. Perception
of Self and Others
Advanced Technical Communication
Skills II
Autumn Semester (1-3-0) (Every Year)
Prof. Koji TOKIMATSU and Prof. Osamu KUSAKABE
[Aims and Scope]
This course is designed to further improve technical
communication skills.
1. Adversity Quotient- (IQ and
EQ will be mentioned)
2. Constructive Communication
Climate
3. Communicating Competently
with Non-verbal codes
4. Interpersonal Conflict
Management
5. Team Building
6. Audience Analysis
7. Personality Profiling
8. Report Writing
9. Power Talk
Advanced Course on Coastal
Environments
Autumn Semester (2-0-0) (Even Years)
Prof. Kazuo NADAOKA
[Aims and Outline]
I. Coastal
zone is subjected to large environmental impacts as well as various natural
phenomena such as waves and currents. Theories and numerical simulation methods
related to these aspects will be lectured with some recent topics on the
improvement of coastal environments.
II.
1. Physics of Water Waves:
Basic
Theory/Nonlinear Wave Theories/Wave Breaking and Related Phenomena/Wind Waves
and Random Waves/Various Wave Models and Numerical Simulation
2. Physics of Coastal Currents:
Nearshore Currents/Tidal and Ocean Currents
3. Nearshore Sediment Transport
and Beach Deformation: Mechanism of Sediment Transport/ Budget of Sediment Transport
Rate and Resultant/ Beach Deformation/Control of Littoral Drift
4. Environmental Hydraulics in
Coastal Zone: Introduction/Physical Environments in Coastal Zone/Control and
Improvement of Coastal Environments
Regional Atmospheric Environment
Autumn Semester (2-0-0) (Even Years)
Assoc. Prof. Manabu KANDA
[Aims and Scopes]
The purpose of this lecture is twofold. One is to understand
the fundamental knowledge and theoretical concepts of Boundary-Layer
Meteorology (BLM). The other is to review the recent applications of BLM to
physical urban planning and civil engineering.
[Outline]
1. Basic theory of Atmospheric
Boundary Layer
1.1 Definition of Atmospheric Boundary Layer
1.2 Diurnal Change of Atmospheric Boundary
Layer
1.3 Constant Flux Layer
1.4 Turbulent Transfer Process
1.5 Radiative Transfer
1.6 Energy Balance of Ground Surface
2. Application to Physical Urban
Planning
2.1 Mesoscale Circulation
2.2 Heat Island Phenomena
2.3 Micrometeorology of Forest Canopy
2.4 Micrometeorology of Urban Canopy
2.5 Energy Balance of Human-body
2.6 Numerical Prediction of Urban Climate
Advanced Course of Fluid Mechanics
Autumn Semester (2-0-0) (Odd Years)
Prof. Syunsuke IKEDA
[Outline]
1. Basics
of Boundary Layer Flow Derivation of Boundary Layer Equation, Physical Implication
2. Blasius
Solution of Flow over Flat plate Matched Asymptotic Expansion, Singular
Perturbation, Velocity, Resistance
3. Finding
of turbulence and Transition to Turbulence Stability Analysis, Orr-Sommerfeld
Equation, Eigen-function
4. Turbulence
Energy Equation Derivation of Turbulence Energy Equation, Energy Balance in
Pipe Flow
5. Correlation
and Energy Spectrum Wiener-Khintchine Relation, Distribution of Spectrum
6. Kolmogorovfs
Energy Spectrum Inertial Subrange, Derivation of -5/3 Power Law, Energy Source
and Sink
7. Zero-Equation
Model (From View Point of Energy Equation) Derivation of Prandtlfs Mixing
Length from Energy Balance Equation
8. One
Equation Model Approximation of Energy Balance Equation
9. K-ƒÃ
Model Examples
10. LES
Concept of LES, Equations
11. Application
of LES to Geophysical Flows
12. Turbulent
Jet
13. Techniques
of Laboratory Experiments
14. Techniques
of Field Observation
Geo-Environmental Engineering
Spring Semester (2-0-0) (Every Year)
Assoc. Prof. Jiro Takemura
[Aims and Scope]
Various aspects on soil contamination and waste disposal
system, i.e., laws, fundamental theories and technologies, will be explained.
[Outline]
1. Introduction
2. Characteristics
of ground water and geochemistry
3. Ground
contamination (I) -- mechanism
4. Ground
contamination (II) -- physical laws
5. Non-aqueous
phase liquid
6. Remediation:
requirement and laws
7. Remediation
technology:
8. Waste
disposal: landfill facility
9. Offshore landfill
10. Monitoring
and prediction methods
11. Simulation
of contaminant process
12. Site
visits
[Evaluation] Attendance, Assignments, examination
[Texts] Handouts will be provided by the lectures.
[Prerequisites] None
Physical Modelling in Geotechnics
Autumn Semester (2-0-0) (Every Year)
Assoc. Prof. Jiro TAKEMURA and Akihoro TAKAHASHI
[Aims and Scope]
This course covers scaling laws and modeling considerations
for physical modeling in geotechnical problems both for static and dynamic
conditions with laboratory exercises.
[Outline]
1. Introduction
+ visit TIT geotechnical centrifuge facilities
2. Similitude
and modeling principles
3. Design
of physical model and model ground preparation
4. Modeling
exercise -1: preparation of dry sand model ground
5. Measurements
strategy and sensors.
6. Modeling
exercise -2: Modeling of liquefaction in 1 G field
7. Modeling
exercise -2: continue
8. Recent
developments in physical modeling - foundation
9. Recent
development in physical modeling - excavation
10. Recent
development in physical modeling - dynamic problems
11. Modeling
exercise -3: Response of a single pile in sand during earthquake in a
centrifuge
12. Modeling
exercise -3: continue
13. Resent
development in physical modeling - cold regionsf problem
14. Examination
and interview
[Evaluation] Assignments, Exercise, Examination
[Texts] Handouts on each topic will be provided by lecture.
[Prerequisites] None
Advanced Mathematical Method for
Infrastructure and Transportation Planning
Spring Semester (2-0-0) (Odd Years)
Assoc. Prof. Daisuke FUKUDA
[Aims]
Mathematical methodologies for infrastructure, transportation
and city planning will be lectured. These include: (1) Advanced statistical
techniques for transportation data analysis, (2) Econometric methods for travel
demand forecasting, and (3) Mathematical optimization techniques for project
evaluation.
[Outline]
1. Introduction
2. Overview of
Systems Analysis
3. Fundamentals
of Mathematical Optimization Problem
(Optimization with equality constraints)
4. Advanced
Topics of Mathematical Optimization Problem
(Optimization with inequality constraints and Dynamic programming)
5. Fundamentals
of Statistical Regression Analysis
(Multiple regression analysis)
6. Advanced
Topics of Statistical Regression Analysis
(Simultaneous equation system, Time-series analysis)
7. Fundamentals
of Discrete Choice Model
(Derivation and Estimation of Logit Model)
8. Advanced
Topics of Discrete Choice Model
(Demand Forecasting, Extended Discrete Choice Models)
[Evaluation] Attendance, Home Work Assignments and
Examination
[Text] Lecture materials will be provided by the lecturer.
Advanced Transportation Planning
and Traffic Engineering
Spring Semester (2-0-0) (Even Years)
Prof. Satoshi FUJII and Assoc. Prof. Daisuke FUKUDA
[Aims]
Analytical method and management measures for road traffic
will be lectured. Regarding road traffic analytical method, traffic flow theory
and traffic assignment theory will be lectured. Regarding management measures,
mobility management measures that accounts for land use and peoplefs life
pattern and psychology will be lectured.
[Outline]
1. Introduction
2. Foundations
of Traffic Flow Theory
3. Modeling Road Traffic Flows (1)
4. Modeling Road Traffic Flows (2)
5. Traffic Assignment on Congested Road
Networks (1)
6. Traffic Assignment on Congested Road
Networks (2)
7. Traffic Assignment on Congested Road
Networks (3)
8. Microscopic & Macroscopic Traffic
Simulation Models
9. Social dilemmas and traffic congestion
10. Mobility
management (1): basic concept
11. Mobility
management (2): basic techniques
12. Mobility
management (3): practical cases
13. Mobility
management (4): advanced practical cases
14. Sustainable
city and transportation
[Evaluation] Reports, discussion and final examination
[Texts] Handouts will be provided by lecture.
Theory of Regional Planning Process
Spring Semester (2-0-0) (Even Years)
Prof. Tetsuo YAI
[Aims and scope]
The systems of Regional Planning and Transportation Planning
are studied in this class. To achieve the goal, first we learn about the
systems of those planning in Europe, USA and Japan, second we study on the
fundamental principle of planning procedures and institutions. Then, we discuss
on the citizen participatory process for those planning fields. This class will
cover some parts of administrative court systems and strategic environmental
assessment in other countries. Planning practices will be discussed during the
class.
[Outline]
1. Overview
2. National
and Regional Planning systems in Japan
3. Planning
systems in Europe and USA
4. Fundamental
theory of planning procedure
5. Public
Involvement process
6. Administrative
court system
7. Planning
and SEA
Stability Problems in Geotechnical
Engineering
Autumn Semester (2-0-0) (Every Year)
Assoc. Prof. Jiro TAKEMURA, Assoc. Prof. Akihiro TAKAHASHI
and Prof. Osamu KUSAKABE
[Aims and Scope]
The lecture focuses on various approaches to stability
problems in geotechnical engineering, including limit equilibrium method, limit
analysis and slip line method. The lecture also covers soil-structure
interaction problems, seismic stability problems and recent ground improvement
methods for increasing the stability of the structures.
[Outline]
1. Introduction
2. Stability
analysis
1) limit equilibrium
2) limit analysis
3) slip line method
3. Soil-Structure
Interaction problems
1) pile-soil interaction
2) braced wall excavation
4. Underground
construction
5. Soil
improvements & reinforcement
6. Design
philosophy and design code
[Evaluation] Attendance, Assignments and Examination
[Texts] Handouts will be provided by the lectures.
[Prerequisites] None
Mechanics of Geomaterials
Spring Semester (2-0-0) (Every Year)
Prof. Osamu KUSAKABE and Associate Prof. Thirapong PIPATPONGSA
[Aims and Scope]
Explain mechanical behaviour of various geomaterials
[Outline]
1.
Behaviour of grains and packing of granular materials
2.
Stress space and failure criteria
3. Micro-scopic
view of geo-materials
4. Sampling
and disturbance
5. Behaviour
of naturally deposit soils
6. Behaviour
of improved geo-materials
7. Behaviour
of reinforced geo-materials
8. Time
dependent behaviour of geo-materials
9. Constitutive
equations
[Evaluation] Assignments, Examination, interview
[Texts] Handouts on each topic will be provided by lectures.
[Prerequisites] None
Advanced Geotechnical Engineering
Autumn Semester (2-0-0) (Odd Year)
Assoc. Prof. Thirapong PIPATPONGSA
[Aims and scope]
The course aims to provide the theoretical framework and
backgrounds of advanced geomechanics consisting of basic theories of
stress-strain-strength relations of geomaterial, formulation of the rate
constitutive models, numerical analyses and computational techniques. Basic to
advanced Engineering examples will be introduced throughout the study to create
logics of application in International Development Engineering practice.
[Outline]
1. Mathematical
foundation
2. Elasticity
and Plasticity
3. Yield
and hardening functions
4. Failure
criteria
5. Strength
anisotropy
6. Constitutive
laws
7. Stiffness
moduli
8. Parameter
determinations
9. Numerical
analyses
10. Application
in engineering practice
[Evaluation]
Apart from mid-term and final examinations, students are
evaluated regularly through a series of homework assignments which expected
students to show their abilities to interpret mathematical notations appeared
in the theory into numerical procedures and application.
[Text] Teaching materials are distributed.
[Prerequisites] None
Seismic Design of Urban
Infrastructures
Spring Semester (2-0-0) (Every Year)
Professor Kazuhiko KAWASHIMA
[Aims and Scopes]
Enhancing seismic performance of urban infrastructures is
essential to mitigate loss of function of urban areas during and after a
significant earthquake. Seismic
design of urban infrastructures is an important part of securing the seismic performance
of urban infrastructures. Emphasis
of this lecture will be placed on the seismic design of transportation
facilities including bridges and underground structures in soft soil deposits.
[Outline]
1. Damage
of urban infrastructures in past earthquakes
2. Engineering
characterization of ground motions (1)
3. Engineering
characterization of ground motions (2)
4. Dynamic
response analysis of bridges
5. Strength
and ductility of reinforced concrete members (1)
6. Strength
and ductility of reinforced concrete members (2)
7. Strength
and ductility of reinforced concrete members (3)
8. Seismic
response of bridges (1)
9. Seismic
response of bridges (2)
10. Seismic
design (1)
11. Seismic
design (2)
12. Performance-based
seismic design
13. Evaluations
of seismic vulnerability
14. Seismic
retrofit
[Evaluation] Report and Examination
[Text] Original texts are provided by the lecturer. They can
be downloaded from HP.
[Prerequisites] Require basic knowledge on structural
analysis and dynamics of structure
Seismic Response Modification of
Urban Infrastructures
Autumn Semester (2-0-0) (Every Year)
Professor Kazuhiko KAWASHIMA
[Aims and Scopes]
A variety of seismic response modification technologies are
effectively used to mitigate damage of urban infrastructures during a
significant earthquake. Isolation of underground structures from the
surrounding soft soils is often used to mitigate the response. Various damper
technologies are used in not only standard bridges but also long-span bridges.
Pocking isolation is attracting increased interest. Emphasis of the lecture
will be places on the seismic design of transportation facilities including
bridges and underground structures in soft soil deposits.
[Outline]
1. Demand
of seismic response modification based on past damage
2. Response
modification using viscous damper
3. Period
shift in using seismic isolation
4. Effect
of inelastic response of columns in seismic isolation
5. Effective
of poundings
6. Design
practice of isolator and dampers
7. Design
practice of seismic isolation
8. Implementation
of seismic isolation
9. Technical
development in seismic isolation
10. Seismic
response modification of superstructures
11. Rocking
isolation
12. Application
of seismic isolation to seismic retrofit
13. Isolation
to underground structures
[Evaluation] Report and Examination
[Texts] Original texts are provided by the lecturer. They can
be downloaded from HP.
[Prerequisites] Require basic knowledge on structural
analysis and dynamics of structures.
Advanced Concrete Technology
Autumn Semester (2-0-0) (Even Years)
Prof. Nobuaki OTSUKI
[Aims and Scopes]
Lectures on the state of the art of concrete technology will
be presented, including some topics related to developing countries.
[Outline]
1. Introduction
2. Cementitious
materials|past, present and future
3. Structure
of hardened concrete
4. Strength
5. Cements
(1)
6. Cements
(2)
7. Admixtures
(1)
8. Admixtures
(2)
9. Aggregates
10. Light
weight Aggregates
11. Flowable
concrete, including anti-washout concrete
12. Pre-stressed
concrete
13. Durability
14. Maintenance
[Evaluation] By examination
[Texts] Ref. Concrete, Prentice Hall
[Prerequisites] None, however, basic knowledge of
undergraduate level may be necessary
Mechanics of Structural Concrete
Spring Semester (2-0-0) (Odd Years)
Prof. Junichiro NIWA
[Aims and Scopes]
Fundamental mechanical behaviors of structural concrete will
be explained.
Some concepts for the limit state design method will also be
given.
[Outline]
1. Introduction
2. Structural
Design Concept of Concrete Structures
3. Ultimate
Limit States
3.1 Flexural Capacity of RC Members
3.2 Capacity of RC Members Subjected to
Combined Flexural Moment and Axial Force
3.3 Shear Capacity of RC Members
3.4 Application of Fracture Mechanics
3.5 Size Effect in Diagonal Tension Strength
3.6 Lattice Model Analysis
3.7 Torsion Capacity of RC Members
4. Serviceability
Limit State
5. Fatigue
Limit States
6. Special
Topics
[Evaluation] Attendance, Reports and Examination
[Text] Lecture notes will be provided by the lecturer.
[Prerequisites] None
Durability and Maintenance of
Construction Materials
Spring Semester (2-0-0) (Even Years)
Prof. Nobuaki OTSUKI
[Aim]
Lectures on durability and maintenance of construction
materials including concrete and steel, especially related to developing
countries.
[Outline]
1. Introduction
and fundamental theories
2. Corrosion
of steel- Introduction
3. Corrosion
mechanism (1)
4. Corrosion
mechanism (2)
5. Prevention
methods
6. Durability
of concrete materials and structures
7. Deterioration
mechanisms (Alkali aggregate reaction, carbonation)
8. Deterioration
mechanism (Chloride attack, chemical attack)
9. Prevention
methods
10. Reinforced
plastics durability
11. Maintenance
strategy
12. Life
Cycle cost
13. Life
cycle story of structures in marine environment
14. Environmental
effects
[Evaluation] By examination
[Text] Handouts will be provided by the lecturer.
[Prerequisites] Fundamental knowledge of undergraduate course
Fracture Control Design of Steel
Structures
Autumn Semester (2-0-0) (Odd Years)
Prof. Chitoshi MIKI
[Aims]
Damage cases in steel structures are categorized and the
control design concepts for fracture are lectured.
[Outline]
1. Classification
of Fracture Modes if Steel Structures
2. Damage
Cases I Steel Structures during Earthquakes
3. Fundamental
Concepts of Fracture Mechanics
4. Fracture
Toughness of Steels
5. Predominant
Factors of Brittle Fracture
6. Fatigue
Strength of Structural Elements
7. Nominal
Stress Based Fatigue Design
8. Structural
Stress Based Fatigue Design
9. Quality
Control of Structural Elements
10. Fatigue
Strength Improvement Methods
11. Maintenance
of Steel Bridges
12. Characteristics
and Prevention of Brittle Fracture during Earthquakes
13. Lessons
learned from Failure
14. Discussions:
Case Studies
[Evaluation] 5 Reports (50%), Examinations (50%)
Analysis of Vibration and Elastic
Wave
Spring Semester (2-0-0) (Odd Years)
Prof. Sohichi HIROSE
[Aims]
Theories of vibration and elastodynamic waves will be
introduced and some engineering applications are presented.
[Outline]
1. Theory of wave and vibration
for one dimensional problem
1-1.
Fundamental equations
1-2.
Reflection and transmission
1-3.
Dispersive waves
1-4.
Fundamental solutions and integral formulation
2. Theory
of elastodynamics
2-1.
Fundamental equations
2-2.
Reflection and transmission of plane waves
2-3.
Surface waves
2-4.
Fundamental solutions and Greenfs functions
2-5.
Integral representation of elastic waves
2-6.
Numerical analysis of elastic waves
3. Engineering
applications of wave and vibration
3-1.
Application in seismic engineering
3-2.
Application in nondestructive testing
[Evaluation] Report (20%) and Examination (80%)
Retrofit Engineering for Urban
Infrastructures
Autumn Semester (2-0-0) (Even Years)
Prof. Chitoshi MIKI
[Aims]
Maintenance problems in urban infrastructures including
damage cases, repair/retrofitting methods, and health evaluation are presented.
[Outline]
1. Recent
Problems in Urban Infrastructures
2. Classification
and Causes of Deterioration of Infrastructures
3. Life
Cycle Cost Evaluation
4. Strategy
of Health and Damage Assessment of Existing Structures
5. Inspection
and Measurements
6. Application
and Recent Problems of Nondestructive Evaluations
7. Health
Monitoring Systems with Sensors for Damage Detection
8. Evaluation
of Actual Strengths of Existing Structures
9. Ultimate
Strengths of Deteriorated Structural Elements
10. Retrofitting
of Corroded Structural Elements
11. Seismic
Retrofitting of Deteriorated Structural Elements
12. Fatigue
Retrofitting of Deteriorated Structural Elements
13. Strengths
of Repaired Structural Elements and Structures
14. Discussion:
Case Studies
[Evaluation] 5 Reports (50%), examination (50%)
Introduction to Solid Mechanics
Spring Semester (2-0-0) (Every Year)
Assoc. Prof. Anil C. WIJEYEWICKREMA
[Aims]
The course is designed for the students to attain the
following four objectives:
(1) Understand index notation used in
equations in any subject area.
(2) Understand the fundamentals of
stresses and strains.
(3) Obtain a good knowledge of linear
elasticity.
(4) To be able to formulate and solve
basic problems in solid mechanics.
[Outline]
1. Mathematical
preliminaries -- Index notation
2. Mathematical
preliminaries -- Vectors and Cartesian tensors
3. Mathematical
preliminaries - Eigen-value problems, vector and tensor calculus
4. Stress
and strain - Stresses, traction and equilibrium equations
5. Stress
and strain - Principal stress and maximum shear stress
6. Stress
and strain - Strain tensor
7. Stress
and strain - Cylindrical polar coordinates
8. Stress
and strain - Spherical coordinates
9. Linear
elasticity? Hookefs law
10. Linear
elasticity? Introduction to anisotropic elasticity
11. Elastostatic
plane problems - Classification of two-dimensional elasticity problems
12. Elastostatic
plane problems - Airy stress functions
13. Elastostatic
plane problems - Infinite plate problem and Kirsch solution
14. Elastostatic
plane problems - Infinite plane with a uniform body force in a circular region
15. Elastostatic
plane problems - Hertz solution
[Evaluation] Homework - 20%, Quizzes - 20% and Final exam -
60%
[Texts] Timoshenko, S. P. and Goodier, J. N., 1970, gTheory
of Elasticityh, 3rd edition, Mc-Graw-Hill, New York / Barber, J. R., 2002,
gElasticityh, 2nd edition, Kluwer, Dordrecht.
[Prerequisites] None
Advanced Course on Elasticity
Theory
Autumn Semester (2-0-0) (Every Year)
Assoc. Prof. Anil C. WIJEYEWICKREMA
[Aims and Scope]
Non-linear elastic behavior is studied in detail. Anisotropic
elasticity will also be introduced.
[Outline]
1. Finite
Elastic Deformations -- Mathematical preliminaries (Cartesian tensors)
2. Finite
Elastic Deformations -- Mathematical preliminaries (Tensor algebra)
3. Finite
Elastic Deformations -- Kinematics (Configurations and motions)
4. Finite
Elastic Deformations -- Kinematics (Deformation gradient and deformation of
volume and surface elements)
5. Finite
Elastic Deformations -- Kinematics (Strain, stretch, extension and shear)
6. Finite
Elastic Deformations -- Kinematics (Geometrical interpretation of the
deformation)
7. Analysis
of motion -- Deformation and strain rates
8. Balance
laws
9. Stress
tensors -- Cauchy stress tensor
10. Stress
tensors -- Nominal stress tensor
11. Conjugate
stress analysis
12. Constitutive
laws
13. Anisotropic
Elasticity -- Linear anisotropic elasticity
14. Anisotropic
Elasticity -- Lekhnitskii formalism
15. Anisotropic
Elasticity -- Stroh formalism
[Evaluation] Home Work Assignments and Examination
[Texts] Holzapfel, G. A., 2001, gNonlinear solid mechanicsh,
John Wiley, Chichester.
Ogden, R. W., 1984, gNon-linear elastic deformationsh, Ellis
Horwood, Chichester, also published by Dover publications, New York in 1997.
Ting, T. C. T., 1996, gAnisotropic elasticityh, Oxford University Press, New
York.
[Prerequisites] Students should have previously followed a
course on Fundamentals of Elasticity or Introduction to Solid Mechanics.
Principles of Construction
Management
Autumn Semester (2-0-0) (Odd Years)
Assoc. Prof. Keisuke MATSUKAWA
[Aims and Scopes]
Considering international construction projects, elements of
construction/project management will be lectured focusing on basic
knowledge/skills/methodology, such as scheduling, cost management, risk
management, bid, contract, legal issues, and project cash flow.
[Outline]
1. Course
Introduction/ General Flow and Scheme of Construction Project (1)
2. General
Flow and Scheme of Construction Project (2), - Bid/Contract (1)
3. Bid/Contract
(2)
4. Time
Management (1)
5. Time
Management (2)
6. Cost
Management (1)
7. Cost
Management (2)
8. Estimation
9. Project
Funding / Cash Flow
10. Special
Topics on Management (1), - Client Management -
11. Risk
Management
12. Legal
Issue, Claim (1)
13. Legal
Issue, Claim (2)
14. Special
Topics on Management (2), - Project Case - / Course Closure
[Evaluation]
Final Report (50%) + Exercise (30%) + Participation (20%)
[Text] gConstruction Managementh by Daniel Halpin/ gA Guide
to the Project Management Body of Knowledgeh by PMI
[Prerequisites] None
Civil Engineering Analysis
Autumn Semester (2-0-0) (Odd Years)
Prof. Sohichi HIROSE
[Amis]
Lecture on fundamentals of forward and inverse analyses of
initial and boundary value problems in civil engineering
[Outline]
1. Introduction – forward and inverse
problems
2. Variational method 1
3. Variational method 2
4. Variational method 3
5. Weighted residual method
6. Finite element method 1
7. Finite element method 2
8. Boundary element method 1
9. Boundary element method 2
10.
Numerical implementation
11. Linearized inverse problems
12. Generalized inverse matrix
13. Instability and regularization of
inverse problems
[Evaluation] Report (20%) and Examination (80%)
Advanced Computational Method in Civil
Engineering
Spring Semester (2-0-0) (Even Years)
Assoc. Prof. Tsuyoshi ICHIMURA
[Aims]
Basic and advanced topics in finite element analysis will be
lectured: formulation, mesh generation, visualization and solver.
[Outline]
1. Introduction
2. Formulation
of Finite Element Method
2.1. 1D Poissonfs problem
with linear element
2.2. 2D Poissonfs
problem with triangle element
2.3. 2D Poissonfs
problem with isoparametric element
2.4. 2D elastic problem
with isoparametric element
2.5. 3D elastic problem
with isoparametric element
3. Mesh
generation
4. Solver
5. Visualization
6. Programming
[Evaluation]
Home Work Assignments and Examination
[Text]
Lecture materials will be provided by the lecturer.
Rural Telecommunications
Autumn Semester (2-0-0) (Every Year)
Prof. Jun-ichi TAKADA
[Aims]
Telecommunications enable the communications instantly
between any points in the world. Moreover, it has become common understanding
that the telecommunication infrastructure is indispensable for the development
of the industry and economy. However, the reality is very severe in the
developing world, especially in rural and remote areas. Imbalance of the
distribution of telecommunications in the world has been intolerable for the
long time. This lecture overviews the historical aspects and the enabling
technologies of rural telecommunications, both in the social and the technical
aspects.
[Outline]
1. Introduction:
Role of telecommunications in the developing areas
2. Historical
overview of the rural telecommunications - gMissing Linkh in 1984
3. Current
status of the rural telecommunications - 20 years after gMissing Linkh
4. Access
infrastructure (1) - Use of amateur radio technology
5. Access
infrastructure (2) - Cellular and personal communication systems
6. Access
infrastructure (3) - Satellite communications
7. Access
infrastructure (4) - TCP/IP based wireless network
8. Access
infrastructure (5) - IEEE 802.11/16/20
9. Access
infrastructure (6) - IEEE 802.22: Cognitive radio
10. Access
infrastructure (7) - Power line communications
11. Information
technology (1) - User terminals
12. Information
technology (2) - Open source for rural telecommunications
13. Case
study taken from ITU-D FG7 database
14. Case
presentations by students
Basic Theories for Information
Processing
Autumn Semester (2-0-0) (Odd Years)
Assoc. Prof. Yukihiko YAMASHITA
[Aims]
The objective of this course is to provide basic techniques
of statistical processing and optimization for international development
engineering. In order to understand those techniques basic mathematics for them
is also provided.
[Outline]
1. Introduction
2. Eigenvalue
decomposition and singular value decomposition
3. Generalized
inverses of matrix
4. Maximum
gradient method
5. Conjugate
gradient method
6. Newton
method
7. Quasi-Newton
method
8. Lagrangefs
method
9. Penalty
method
10. Maximum
likelihood estimator
11. Bayesian
estimator
12. Cramer-Rao
lower bound
New Trends in Numerical Analysis
Autumn Semester (2-0-0) (Odd Years)
Prof. Yoshihiro MOCHIMARU
[Aims]
Inclusive targets are: treatment of partial differential
equations, multiplicity of solutions, stability, and spectral finite difference
analysis.
[Outline]
1. Nonlinear
Partial Differential Equations
2. Possibility
of Existence of Solutions
3. Multiplicity
of Solutions
4. Discretization
5. Stability
with Respect to Time
6. Spectral
Decomposition
7. Conformal
Mapping
8. Spectral
Finite Difference Analysis
Welding and Joining Technology
Spring Semester (2-0-0) (Even Year)
Assoc. Prof. Kunio TAKAHASHI
[Aims]
Welding and joining processes are the key technology in the
industry. The processes will be reviewed including recent advanced processes.
Phenomena and mechanisms of the processes will be explained based on material
science, mechanics, and electrical engineering.
[Outline]
1. History
of welding and joining processes
2. Required
condition for welding and joining processes
3. Method
and its classification
4. Arc
welding phenomena
5. Arc
welding power sources and equipments
6. Cutting
7. Materials
and their behavior in welding and joining
8. Metallurgy
of steel and heat treatment
9. Heat
input and cooling rate
10. Weld
defects
11. Mechanical
properties of weld joints
12. Residual
stress and weld deformation
13. Weld
design
Perspective Understanding of
Various Kinds of Material
Autumn Semester (2-0-0) (Even Year)
Assoc. Prof. Kunio TAKAHASHI
[Aims]
Material properties such as latent heat, electric
conductance, diffusion coefficient, elasticity, strength, etc... will be
explained for variety of materials such as metals, ceramics, semiconductors,
concretes, composites, etc... from the universal view point using bases of
quantum mechanics, statistical mechanics, thermo-dynamics, etc...
[Outline]
1. Physics
for an universal feature of materials
2. Electric
properties of materials
3. Mechanical
properties of materials
4. Thermal
properties of materials
5. Chemical
properties of materials
6. Metals
7. Insulators
8. Semi-conductors
9. Ceramics
10. Carbon
steels
11. Concrete
Applied Economics for Engineers
Spring Semester (2-0-0) (Every Year)
Assoc. Prof. Naoya ABE
[Aims]
This course aims to provide basic concepts and theories of
microeconomics and macroeconomics to potential engineering graduate students
for their easy (but not complete) access to current economic topics and the
fields of applied economics such as environmental economics and development
economics.
[Outline]
1. Microeconomics
(1): consumer: choice and demand
2. Microeconomics
(2): firm: production and supply
3. Microeconomics
(3): market mechanism
4. Microeconomics
(4): limits of the market
5. Macroeconomics
(1): national income
6. Macroeconomics
(2): economic growth
7. Macroeconomics
(3): exchange rates
8. Environmental
Economics (1): market failure and environmental policies
9. Environmental
Economics (2): externalities and incentives
10. Environmental
Economics (3): basic idea of the economic valuation of the environment
11. Development
economics (1): wealth distribution and poverty
12. Development
economics (2): government and policies
13. Development
economics (3): foreign direct investment and trade
14. Discussion:
applied economics and engineering
Project Evaluation for Sustainable
Infrastructure
Spring Semester (2-0-0) (Every Year)
Assoc. Prof. Shinya HANAOKA
[Background]
This course aims to provide the methods necessary to
undertake project evaluation and cost benefit analysis for sustainable
infrastructure. The methods comprise of microeconomics background, cost benefit
analysis, valuing market and non-market goods, and other technical issues. Case
studies of various infrastructures are also provided.
[Outline]
1.@Introduction to Project Evaluation
2. Basics of Microeconomic Theory
3. Foundations of Cost Benefit Analysis
4. Valuing Benefits and Costs in Primary
Markets
5. Valuing Benefits and Costs in Secondary
Markets
6. Discounting Benefit and Costs
7. Existence Value
8. Valuing Market Goods
9. Valuing Non-Market Goods: Revealed
Preference
10. Valuing Non-Market Goods: Stated
Preference
11. Related Methods and Accuracy
12. Case Studies: Transport Infrastructures
13. Case Studies: Other Infrastructures
Advanced Topics in Civil
Engineering I
Spring Semester (2-0-0) (Every Year)
Unfixed: Visiting Professor
Visiting Associate Professor Jan-Dirk Schmöcker
[Aims and Scope]
Good transportation networks are a key to liveable cities.
The course aims to equip students with a broad understanding of the problems
faced in todayfs networks. Often mentioned desired aspects are qualities such
as Accessibility, Reliability and Sustainability. The various aspects of these
and other terms are discussed. This is integrated with a discussion on the
tools available to transportation planners to achieve such objectives. The
course will be given in English and students will be asked to make
presentations.]
[Outline]
- Vision
of Cities
- Traffic
Management Objectives
- Network
Reliability
- Accessibility
(Access to destination, Access for all)
- Sustainable
Transportation
- Intelligent
Transportation Systems
Advanced Topics in Civil
Engineering II
Autumn Semester (2-0-0) (Every Year)
Unfixed: Visiting Professor
[Aims and Scope]
The aim of the course is to introduce concepts and techniques
used in the analysis of transport and traffic movement. Further, to provide the
student fundamental knowledge on transport planning theory and processes, as
well as knowledge and understanding of the basic principles and practice of urban
traffic and transport management.
[Outline]
- Traffic
Flow Theory
- Traffic
Surveys and Measurement
- Speed
Data Analysis
- 4-Stage
modelling: Trip Generation, Trip Distribution, Mode Choice, Traffic Assignment
- Signal
Control
- Public
Transport Priority
- Microsimulation
International Development
Engineering Field Work A and B
A : Spring Semester (0-0-1) / B : Autumn Semester (0-0-1)
Chair, Department of International Development Engineering
[Aims]
Students shall plan and practice the activities related to
the international development engineering. Through the experience of these
activities, the students can learn the connection between the course works and
the real development.
[Outline]
1. Approval
of the working plan by supervisor and department head
2. Activities
(more than one week)
3. Submission
of the report to supervisor and department head
4. Oral
presentation of the report
(Examples of activities)
œ Internship
or training in foreign or domestic companies.
œ Internship
or working experience in the organizations related to the international
development.
œ Field
study related to the lectures given in the department.
œ Review
and survey of state-of-art technologies by participating to an international
conference. Visit of other research institution to give presentation or to
discuss on research topic, by utilizing this occasion.
Development and Environmental
Engineering Off-Campus Project I
Spring Semester
(0-4-0) for
Doctor Degree
Development and Environmental
Engineering Off-Campus Project II
Autumn Semester
(0-4-0) for
Doctor Degree
[Aims and scope]
Either of above two projects is required for Doctoral degree.
The student will take part in an actual project done by an institution or
private company. Project period is
from three to six months, in which the student should work more than 160 hrs in
total. Through this internship
projects the student will experience the actual practice in her/his own field
and have proper prospects of her/his future profession.
Special Experiments of Development and
Environmental Engineering I, III
1st (0-0-1) for
Master Degree
[Aims and scope]
Experiments, exercises and field works on topics relating to
each field under the supervision by each supervisor and course coordinator.
Special Experiments of Development
and Environmental Engineering II, IV
2nd Semester
(0-0-1) for
Master Degree
[Aims and scope]
Experiments, exercises and field works on topics relating to
each field under the supervision by each supervisor and course coordinator.
Seminar in Development and
Environmental Engineering I, III
1st Semester
(0-1-0) for
Master Degree
[Aims and scope]
Colloquium on topics relating to each course by means of
reading research papers and books, and discussion with each supervisor and
course coordinator.
Seminar in Development and
Environmental Engineering II, IV
2nd Semester
(0-1-0) for
Master Degree
[Aims and scope]
Colloquium on topics relating to each course by means of
reading research papers and books, and discussion with each supervisor and
course coordinator.
Seminar in Development and
Environmental Engineering V, VII, IX
1st Semester
(0-2-0) for
Doctor Degree
[Aims and scope]
All are offered for Master degree holders. Advanced and high
level researches including colloquium, practice and experiment are required.
Seminar in Development and
Environmental Engineering VI, VIII, X
2nd Semester
(0-2-0) for
Doctor Degree
[Aims and scope]
All are offered for Master degree holders. Advanced and high
level researches including colloquium, practice and experiment are required.
5.2 Nuclear Engineering Course
Basic Nuclear Physics
2010 Spring Semester (2-0-0) (Even Years)
Assoc. Prof. Masayuki IGASHIRA
[Aims]
Lecture on nuclear physics will be given as a basic subject
of nuclear engineering.
[Outline]
1. General
Properties of Nuclei (Binding Energy, Statistics, Mass Formula, etc)
2. Nuclear
Structure (Free Fermi Gas Model, Shell Models, Collective Models)
3. Nuclear
Reactions (Formal Theory, Optical Model, Direct Reactions, Compound Nuclear
Reactions, Statistical Model)
Nuclear Reactor Theory
2009 Spring Semester (2-1-0) (Odd Years)
Prof. Hiroshi SEKIMOTO, Assoc. Prof. Toru OBARA
[Aims]
This course will provide an overview of the nuclear energy
system and material transmutation system, and lectures on generation, reaction,
transport and utilization of neutrons. Calculation and analysis technique
appeared in this course will be mastered through exercises and discussions.
[Outline]
1. History of Nuclear Physics and Neutronics
2. Elementary Particles, Nucleus and
Energy, Nuclear Reactions
3. Neutron Induced Reactions
(Reactions, Neutron Flux, Cross Section)
4. Neutron Induced Reactions
(Scattering, Fission)
5. Chain Reaction (Chain Reaction and
Criticality, Neutron Multiplication Factor)
6. Nuclear Reactors (Thermal Reactor,
Fast Reactor)
7. Neutron Transport (Transport
Equation, Slowing-Down Equation)
8. Neutron Transport (Diffusion
Equation, Multi-Group Equation)
9. Time Behavior and Reactor Control
(Delayed Neutron, Reactivity, Feedback)
10. Time Behavior and Reactor Control
(Reactor Kinetics and Safety Analysis)
11. Time Behavior and Reactor Control
(Xe Poisoning, Burn up, Fuel Management)
12. Fusion Neutronics and Shielding
13. Generation and Measurement of
Neutron
14. Equilibrium Nuclear Society
(Material Balance, General Problems)
15. Utilization of Neutrons other than
Power Generation
Nuclear Chemistry and Radiation
Science
2009 Autumn Semester (2-0-0) (Odd Years)
Assoc. Prof. Yasuhisa IKEDA, Assoc. Prof. Yoshihisa MATSUMOTO
[Aims]
The aim of this lecture is to learn fundamental knowledge on
radio-chemistry (nuclear chemistry), radiation science, including
radiation-chemistry, and radiation-material interaction. In addition,
introductive lectures are given on the topics relating radiation protection and
stable isotopes.
[Outline]
1. History
of nuclear chemistry
2. Structure
and properties of the atomic nucleus
3. Types
of radioactive decay and decay law
4. Interaction
of radiation (ƒ¿, ƒÀ and ƒÁ-rays) with matter
5. Measurement
of nuclear radiation
6. Mechanism
of nuclear fission and nuclear reactors
7. Environmental
behavior of radioactive substances
8. Biological
effects of radiation
9. Radiation
protection and safery
10. Application
of radiation technology
11. Stable
isotope measurement and isotope effects
Reactor Thermal Hydrodynamics
2009 Autumn Semester (2-0-0) (Odd Years)
Assoc. Prof. Minoru TAKAHASHI, Prof. Hiroyasu MOCHIZUKI
(Univ. of Fukui)
[Aims]
The purpose of this lecture is to study the fundamentals of
heat generation, cooling, energy transport and energy conversion in various
kinds of fission and fusion reactors, and to understand nuclear energy systems.
[Outline]
1. Heat
Generation and Its Transport Systems
2. Heat
Conduction in Fuel Matrixes
3. Heat
Transfer by Fluid Flow
4. Heat
Transfer with Phase Change
5. Thermo-Hydraulic
Phenomena in a Two-Phase Flow
Nuclear Reactor Safety
2009 Spring Semester (2-0-0) (Odd Years)
Prof. Masaki SAITO, Prof. Hisashi NINOKATA
[Aims]
This subject aims to introduce safety principles for nuclear
power plants.
[Outline]
1. Safety
Characteristics of LWR and FBR
2. Safety
Culture
3. Nuclear
Reactor Accidents
4. Safety
Improvements and Advanced Nuclear Reactors
Nuclear Energy Systems
2009 Autumn Semester (2-0-0) (Odd Years)
Prof. Hisashi NINOKATA, Assoc. Prof. Shunji IIO
[Aims]
An introductory course is given to the nuclear power reactor
systems including fission power reactors and fusion reactors. Fundamental
principles governing nuclear fission chain reactions and fusion are described
in a manner that renders the transition to practical nuclear reactor design
methods. Also future nuclear reactor systems are discussed with respect to
generation of energy, fuel breeding, incineration of radio-active materials and
safety.
[Outline]
1. Principles
of Nuclear Reactor Design
2. Light
Water Reactor Power Plant
3. Fast
Breeder Reactor Plant
4. Fundamentals
of Fusion Reactors
5. Fusion
Reactor Design
Energy Systems and Environment
2010 Spring Semester (2-0-0) (Even Years)
Assoc. Prof. Yukitaka KATO, Prof. Yoshio YOSHIZAWA
[Aims]
The lecture is to provide knowledge of advanced energy
systems for the sustainable global environment. A variety of energy sources and
usage systems, related thermodynamics and transport phenomena in the systems,
and the possibility of the systems are discussed. The feasibility of renewable
and nuclear energy systems, and technologies for energy conversion, and also
the studies on hydrogen production and fuel cell are provided.
[Outline]
1. Effects
of Fossil Fuel Burning on the Global Environment
2. General
Aspects of Energy and Environmental Problems
3. Advanced
Energy Conversion Technologies
Nuclear Materials Science
2008 Autumn Semester (2-0-0) (Even Years)
Prof. Toyohiko YANO
[Aims]
This is the only lecture concerning materials issues,
including nuclear fuels and incore materials, of nuclear fission and fusion
reactors. The basis is materials science. The topics including are:
manufacturing methods of nuclear fuels, structures of fuels and fuel elements,
moderators, control materials, blanket materials, and structural materials.
Another emphasis is put on fundamentals of radiation damage and irradiation
effects of nuclear reactor materials.
[Outline]
1. Components
of LWR, HWR, LMFBR reactors and material selection
2. Radiation
Damage of Materials
3. Physical
and Chemical Properties of U, UO2, and PuO2
4. Fabrication
Process of Nuclear Fuels
5. Fission
and Fusion Reactor Materials
Accelerators in Applied Research
and Technology
2009 Spring Semester (2-0-0) (Odd Years)
Prof. Toshiyuki HATTORI, Assoc. Prof. Yoshiyuki OGURI
[Aims]
The objective of this course is to present an overview of
accelerator-based research and engineering, which is a growing and vibrant
scientific area. Principles of operation of charged particle accelerators with
different schemes are briefly explained. The lecture on the accelerators is
followed by discussion on the application of accelerators in science and
technology, ranging from fundamental research to medical use.
[Outline]
1. Ion
sources and electron guns
2. Operating
principles of charged particle accelerators
3. Optics
of particle beams
4. Accelerator-based
fundamental research
5. Application
of accelerators in industry
6. Medical
application of accelerators
Plasma Science
2009 Autumn Semester (2-0-0) (Odd Years)
Assoc. Prof. Hiroshi AKATSUKA, Prof. Takayuki AOKI
[Aims]
This subject aims to introduce fundamental physics of plasmas
and their applications. This lecture also covers experimental methods to
generate plasmas, diagnostics, fundamental equations to describe weakly ionized
plasmas, applications for material processing, and high density plasmas.
[Outline]
1. Fundamental
Concepts in Plasmas
2. Plasma
Generation
3. Governing
Equations of Plasmas
4. Plasma
Properties
5. Plasma
Applications
Reactor Chemistry and Chemical
Engineering
2010 Spring Semester (2-0-0) (Even Years)
Assoc. Prof. Yasuhisa IKEDA
[Aims]
Technologies in nuclear fuel cycle, e.g., fuel fabrication,
uranium enrichment, fuel reprocessing, waste management, will be explained.
[Outline]
1. Introduction
2. Uranium
chemistry
3. Properties
of actinide elements
4. Mining
and refining of nuclear fuel materials
5. Nuclear
fuel cycle
6. Chemistry
of coolant
7. Corrosion
in reactors
8. Reactor
maintenance
9. Radioactive
waste treatment
10. Radioactive
waste disposal
11. Application
of nuclear energy to chemical industries
Computational Fluid Dynamics
2008 Autumn Semester (1-1-0) (Even Years)
Prof. Takayuki AOKI
[Aims]
This course will provide numerical methods of Computational Fluid
Dynamics (CFD). Not only knowledge of numerical schemes but also practical
skill to execute numerical simulation will be obtained. By solving a lot of
sample problems given in the class, programming skill will be mastered.
[Outline]
1. Overview
of Computational Fluid Dynamics
2. Classification
of partial differential equations
3. Numerical
methods for hyperbolic equation
4. Numerical
methods for parabolic and ellipsoidal equations.
5. Algorithms
for Sparse matrix solver.
6. Typical
schemes for compressible and incompressible fluids
7. Parallel
computing of CFD
8. Visualization
of CFD
Nuclear Reactor Design and
Engineering
2008 Autumn Semester (2-0-0) (Even years)
Prof. Hisashi NINOKATA
[Aims]
The lectures provide a basic principle of nuclear power
reactors, advanced theories of nuclear reactor kinetics and thermal hydraulics
and their applications, and in-depth understanding of nuclear reactor safety.
With the fundamental knowledge of nuclear reactor physics as prerequisite, the
lectures will cover the theory and practices in nuclear reactor core design and
safety evaluation.
[Outline]
1. Design
target and approaches, review of nuclear and thermal hydraulics principles
2. Core
nuclear characteristics and design, fast reactors and thermal reactors
3. Nuclear
reactor dynamics including one-point kinetics,
4. Perturbation
theory, reactivity feedbacks
5. Thermal-hydraulics
design, design limits, hot spot factors for LWRs and LMFBRs
6. Subchannel
analysis
7. Structural
engineering and design principle
8. LWR
plant safety systems and plant dynamics simulation
9. Probabilistic
safety analysis - Introduction to risk-informed design approach
10. Nuclear
reactor safety target, reactor protection systems, EPZ
11. Integrated
primary system reactor - IRIS and safety by design
12. LMFBR
design practices of the MONJU plant
Experiments in Nuclear Engineering I
(J)
Spring Semester (0-0-2)
[Aims]
To obtain basic experimental technique and experience,
special experimental work is made at nuclear research facilities outside Tokyo
Institute of Technology. These experiments are scheduled during or prior summer
vacation for 1 week. Students belonging to the nuclear engineering course are
strongly recommended to attend one of the following programs.
[Outline]
1. Nuclear
reactor physics experiments at the Kyoto University Reactor.
2. Nuclear
reactor physics experiments at the Japan Atomic Energy Agency.
Nuclear Engineering Off-Campus
Project I
Spring Semester (0-4-0)
Academic Advisor
Nuclear Engineering Off-Campus
Project II
Autumn Semester (0-4-0)
Academic Advisor
[Aims & Outline]
Students can participate in Off-Campus Projects. The projects
provided by out-side organizations of universities, research institutes,
industries, administrative agencies etc. Duration of each Off-Campus Project is
from 3 months to 6 months (minimum time is 160 hours). The Off-Campus Projects
I or II is depended with duration time of the project.
Seminar in Nuclear Engineering I -
IV (J)
Masterfs Course: Spring Semester: I, III, Autumn Semester:
II, IV (0-1-0)
[Aims & Outline]
Compulsory subject for Master Course students. This program
is conducted through reading of selected books and papers and discussions on
the topics in the relevant scientific field with advising professors.
Seminar in Nuclear Engineering V- X
(J)
Doctoral Course: Spring Semester: V, VII, IX, Autumn
Semester: VI, VIII, X (0-2-0)
[Aims & Outline]
This subject is an advanced program for students in Doctoral
Course, conducted in the same way as in the colloquium.
(Note) (J): Joint
classes of Japanese Language Course and International Course.
5.3 Infrastructure Metallic
Materials Course
Applied Diffraction Crystallography
in Metals and Alloys
Spring Semester (2-0-0) (Odd Years)
Prof. Yoshio Nakamura
[Aims]
Fundamentals of crystallography and structural characterization
by diffraction technique are introduced especially to students who study
metallurgy.
[Outline]
1. Symmetry
description of crystal
2. How
to describe structure of crystals
3. Crystal
symmetry and physical properties
4. Ordered
structure and modulated structure
5. Diffraction
from ideal and imperfect crystals
6. X-ray
and Electron diffraction techniques for structural analysis and
characterization
Crystallography
for Microstructural Characterization
Autumn Semester (2-0-0) (Odd
Years)
Assoc. Prof. Toshiyuki Fujii
[Aims & Outline]
This class offers methods of
determining the crystal structure and characterizing the microstructure of
metals. Students will learn about the basic crystallography, stereographic
projection, x-ray and electron diffraction, and electron microscopy. Quizzes
are given out to the students in every class.
Advanced Metal Physics
Autumn Semester (2-0-0) (Odd Years)
Assoc. Prof. Ji Shi
[Aims & Outline]
This course is designed to introduce first-year graduate
students to the fundamentals and recent developments in solid state physics,
especially in relation to metals and alloys. Emphasis is placed on the
electronic structures of solids and related properties. Starting from
introductory quantum mechanics, the course covers following topics: atomic
structure, bonds in metallic and nonmetallic solids, band structure and
semiconductors, transition metals and ferromagnetism, physics and applications
of thin solid films.
Deformation
and Mechanics of Solid Materials
Autumn Semester (2-0-0) (Even
Years)
[Aims
& Outline]
Lattice
defects and their role on mechanical properties of solid materials are
lectured. Topics such as linear elasticity (stress, strain, Hookefs law) and
dislocation theory are included.
Thermodynamics for Metallurgists
Spring Semester (2-0-0) (Even Years)
Assoc. Prof. Kenichi Kawamura
[Aims]
Thermodynamics is a powerful tool for the material processing
and design. This lecture provides the understanding of the thermodynamics from the
basics to the applications, and extends to the defect chemistry in solid oxide.
[Outline]
1. Introduction
2. Basics
of thermodynamics
3. Gibbs
energy
4. Phase
diagram and rule
5. Activity
6. Chemical
reaction
7. Thermodynamic
table
8. Measurement
for thermodynamic data
9. Crystal
defects
10. Solid
state ionics
11. Application
of solid state ionics I
12. Application
of solid state ionics II
Physical Chemistry of Melts
Autumn Semester (2-0-0) (Odd Years)
Prof. Masahiro Susa
[Aims]
This lecture mainly centers upon thermodynamics of metal and
its oxide melts. The term of emeltsf essentially means what the term of
eliquidf does and is often used, in particular, when one refers to the state of
substances which are melted at high temperatures. In this usage, for example,
liquid iron is a kind of melt but liquid water is not. Many metallic materials
are produced via the state of melts and thus understanding of physico-chemical
properties of melts is essential to metallic materials process designing and
its optimization. This lecture ranges from fundamental to slightly applied
thermodynamics relevant to metals, including phase diagrams. The final goal is
to learn how to use the concept of activity and how to interpret phase
diagrams, in particular, for ternary systems containing melts, through many
exercises.
[Outline]
1. Basic
Thermodynamics
First law,
Internal energy and enthalpy, Second law, Entropy, Third law, Gibbs energy and
chemical potential, Chemical equilibria and phase rule, Ellingham diagram
2. Activity
Law of mass
action and concept of activity, Raoultian and Henrian standard activities,
Henrian activities by mole fraction and mass% expressions, Interaction
parameters, Basicity
3. Phase
diagram for binary system
Lever rule, and
eutectic and peritectic systems
4. Phase
diagram for ternary system
Method of
determining composition, Isoplethal studies in systems containing eutectic
reactions, Alkemade lines and composition triangles, Isothermal sections,
Isoplethal studies in systems containing peritectic reactions
Electrochemistry of Metals
Spring Semester (2-0-0) (Odd Years)
Assoc. Prof. Atsushi Nishikata
[Aims]
This course provides a fundamental of electrochemistry for
understanding the corrosion phenomena of metals and alloys.
[Outline]
1. Introduction
2. Electrochemical
thermodynamics (I) Electrode potential, Nernst equation
3. Electrochemical
thermodynamics (II) Potentiometric titrations
4. Electrochemical
thermodynamics (III) Potential - pH diagram
5. Electrochemical
kinetics (I) Mass transfer, rate-determining step
6. Electrochemical
kinetics (II) Polarization curve, Butler-Volmer equation
7. Electrochemical
kinetics (III) Tafel extrapolation, Polarization resistance
8. Anodic
dissolution mechanism of metals
9. Anodic
dissolution mechanism of alloys
10. Passivation
of metals and alloys
11. Forms
of corrosion of Stainless steels
12. Corrosion
of metals, low-alloy-steels, Al, Cu, Ti
Solid State Chemistry in Metal
Oxides
Autumn Semester (2-0-0) (Odd Years)
Prof. Toshio Maruyama
[Aims & Outline]
This lecture is focused on physico-chemical properties of
metal oxides at elevated temperatures from the viewpoint of solid state
chemistry. The topics are
(1) Nature
of chemical bond in metal oxides
(2) Thermodynamics
(3) Defect
chemistry
(4) Diffusion
and ionic conduction
(5) High
Temperature oxidation of metals
(6) Solid
state reaction
Transport Phenomena of Metals and
Alloys
Spring Semester (2-0-0) (Even Years)
Assoc. Prof. Miyuki Kanazawa
[Aims]
The lecture focuses on the basic transport phenomena such as
flow pattern of liquid, mass and heat transport in liquid and solid and
reaction rate at the interface between different phases, which can be seen in
the metal smelting, the production process of electrical materials and so on.
[Outline]
1. Introduction
2. Mass
transport
1) Fickfs law of diffusion
2) Shell mass balances and
boundary conditions
3) Steady-state diffusion
4) Nonsteady-state diffusion
3. Momentum
transport
1) Newtonfs law of viscosity
2) Navier-Stokes equation
3) Laminar flow and turbulent
flow
4) Friction factors
4. Energy
transport
1) Fourierfs law of heat
conduction
2) Shell energy balances and
boundary conditions
5. Dimensional
analysis
1) Buckinghamfs pi theorem
2) Dimensionless numbers for
forced convection and free convection
3) Dimensionless number for heat
conduction
6. Macroscopic
balances
1) Isothermal systems
2) Nonisothermal systems
3) Bernoulli equation
High Temperature Strength of Metals
and Alloys (no class for 2008j
Autumn Semester (2-0-0) (Even Years)
Prof. Takashi Matsuo
[Aims & Outline]
Firstly, well understood high temperature creep deformation
mechanisms, that is, dislocation creep, Nabarro-Herring creep and Coble creep
will be lectured. To make good understanding of the meaning of these three
deformation mechanisms, high temperature creep deformation map must be drawn
according to the text indicating the calculating manner. Secondly, new creep conception will be
lectured to give the image of internal stress.
Phase Transformations in Metals and
Alloys
Autumn Semester (2-0-0) (Even Years)
Assoc. Prof. Masao Takeyama
[Aims]
Physical and mechanical properties of metals and alloys are
directly associated with their microstructures, so it is very important to
understand how to control the microstructures through phase transformations.
This course of lectures covers the fundamental mechanisms of solid/solid phase
transformations and microstructure evolution in ferrous and other materials.
[Outline]
1. Introduction -Basics for studying phase
transformations-
1-1 Thermodynamics and Phase diagrams
1-2 Diffusion
1-3 Diffusional Transformations in solids
1-4 Diffusionless Transformations in solids
2. Microstructures
and Phase transformations in Ferrous Materials
2-1 Phase transformations in iron
2-2 Pearlite
2-3 Bainite
2-4 Martensite
3. Microstructures
of Other alloys
3-1 Titanium and titanium alloys
3-2 Nickel base alloys
4. Phase
transformations in Intermetallics
4-1 Order/disorder transformations
4-2 Ordering and Phase Separation
Microstructures of Metals and
Alloys
Autumn Semester (2-0-0) (Odd Years)
Prof. Tatsuo Sato
[Aims & Outline]
Characteristics and formation mechanisms of various
microstructures of metals and alloys produced during fabrication processes such
as cast/solidification, plastic deformation and heat treatments are comprehensively
introduced. The fundamental correlation between microstructures and mechanical
properties is discussed. The topics on the advanced materials are also
introduced.
Characteristics and Applications of
Intermetallic Alloys
Spring Semester (2-0-0) (Even Years)
[Aims & Outline]
Intermetallic compounds provide very different physical and
chemical properties due to a wide variety of their ordered crystal structures.
Starting from fundamental characteristics of intermetallic compounds strongly depending
on their ordered structures, advanced applications both for structural and
functional are covered with considering strategies for the material design.
Diffusion in Alloys
Autumn Semester (2-0-0) (Even Years)
Assoc. Prof. Masanori Kajihara
[Aims & Outline]
Evolution
of microstructure occurs in many alloy systems at elevated temperatures. Such a
phenomenon is usually controlled by diffusion. On the basis of Fickfs first and
second laws, diffusion can be described mathematically. In the present lecture,
various mathematical methods describing diffusion will be explained.
Alloy
Phase Diagrams
Autumn Semester (2-0-0) (Even
Years)
Assoc. Prof. Hideki Hosoda
[Aims & Outline]
The purpose of this lecture is a
comprehensive understanding of the alloy phase diagrams in the binary and
ternary systems through studying the phase reaction, the phase rule, Gibbs free
energy and related features.
Besides, microstructures are discussed in connection with alloy phase diagrams. Besides, practice is provided in each
class to develop understanding. .
Advanced Ferrous and Non-ferrous
Materials
Autumn Semester (2-0-0) (Even Years)
Prof. Takashi Matsuo
[Aims]
Desirable mechanical characteristics for metallic materials
often result from a phase transformation, which is wrought by a heat treatment.
This lecture covers several different microstructures that may be produced in
both ferrous and non-ferrous alloys depending on heat treatment.
[Outline]
1. Crystal
structure
2. Heat
treatment of ferrous materials
3. Phase
transformation and microstructure of ferrous materials
4. Heat
treatment of non-ferrous alloys
5. Microstructural
evolution in non-ferrous alloys
Science
and Engineering of Solidification
Spring Semester (2-0-0) (Even
years)
Prof. Shinji Kumai
[Aims & Outline]
The
present lecture provides a fundamental knowledge of solidification, from the
scientific to the engineering point of view, covering the recent development
and future prospects. Basic concepts of driving force for solidification,
undercooling, local equilibrium, and interface non-equilibrium are described. A
detailed explanation is also made about dendritic and eutectic growth, as well
as of peritectic, monotectic and behavior of third phase.
Environmental Degradation of
Materials
Autumn Semester (2-0-0) (Even Years)
Prof. Tooru Tsuru
[Aims]
Based on electrochemistry and surface chemistry, the class
offers analytical methods to be applied for degradation mechanisms and its
prevention of infrastructural and functional materials in various environments.
[Outline]
1. Electrochemistry
of Corrosion
1.1 Basics of electrochemistry,
Electrochemical equilibrium, Standard electrode potential, Potential-pH diagram
1.2 Kinetics of electrochemistry,
Butler-Volmer equation, Exchange current density, Overpotential
1.3 Mixed potential theory, Corrosion
potential, Corrosion current, Polarization curve
1.4 Anodic dissolution mechanism: Anodic dissolution of metals and alloys
2. Practical
Corrosion and Degradation of Materials
2.1 Forms of corrosion, Classification of
corrosion, Evaluation methods
2.2 Determination of corrosion, Measurement
of corrosion rate
2.3 Passivity and passive films,
Characteristics of passive films
2.4 Degradation of stainless steel, Localized
corrosion, Pitting and crevice corrosion
2.5 Stress corrosion cracking (SCC),
Environmental brittlement (HE, CF)
3. Environmental
Degradation of Materials
3.1 Novel corrosion resistant materials
3.2 Degradation of electronic devices and
materials
3.3 Degradation of infrastructure and its
evaluation
3.4 Novel methods for evaluation and
measurement of materials degradation
Non-equilibrium Thermodynamics for
Materials Science
Spring Semester (2-0-0) (Odd Years)
Prof. Kazuhiro Nagata
[Aims]
The relation between diffusion flow, electric current and
heat flow in metals and metal oxides in solid or liquid state are discussed
from the viewpoint of irreversible thermodynamics. Non-linear phenomena such as
chemical reactions and viscous flow etc. are also discussed.
[Outline]
1. Irreversible
processes and entropy production
2. Chemical
affinity
3. Phase
stability 1
4. Phase
stability 2
5. Thermodynamics
for transport phenomena
6. Diffusion
7. Thermal
conduction and thermal diffusion
8. Application
of linear irreversible thermodynamics
9. Stability
of stationary state
10. Rate
of excess entropy production
11. Non-linear
reaction rate 1
12. Non-linear
reaction rate 2
13. Phase
transition and chemical reaction rate
14. Interface
phenomena and application to materials
15. Summary
- Skills and Trainings -
Advanced Metallurgical Engineering
Laboratory
Autumn Semester (0-0-4)
[Aims & Outline]
The present lecture provides a chance to understand the
physical, chemical and mechanical properties of metallic materials through the
basic experiments, which include age hardening of aluminum alloys. Heat
treatment of ferrous alloys, tensile properties, corrosion behavior, steel
making, and so on.
Materials Off-Campus Project I, II
Spring and Autumn Semesters (0-0-4)
[Aims & Outline]
This course is designed to experience the research and/or
production in the material companies. The knowledge of metallurgy studied in
Tokyo Tech is expected to utilize in the companies during this internship
program.
Seminar in Materials Science and
Technology I-IV
Spring and Autumn Semesters (0-1-0)
Seminar in Materials Science and
Technology V-X
Spring and Autumn Semesters (0-2-0)
[Aims and scope]
Colloquium on topics relating to each specialty by means of
reading research papers and books, and Discussion with each supervisor and
course coordinator
5.4 Mechanical and Production
Engineering Course
Robot Creation
Spring Semester (April) (2-0-0)
Prof. Shigeo Hirose, Fumihiko E Fukushima
[Aims]
Various projects including the design of new types of robot
systems will be presented, and basic principles as well as creative thinking in
the design of the robot systems will be explained.
[Outline]
(1) Biomechanics
of a snake, and snake-like robots
(2) Development
of a hyper-redundant manipulator
(3) Development
of an articulated body mobile robots
(4) Development
of a snake-like gripper
(5) Biomechanics
of walking animals and walking robots
(6) Mechanisms
and controls of walking robots
(7) Development
of vacuum sucker wall climbing robots
(8) Optimum
design of large DOF robots (GDA and Coupled drive)
(9) Development
of wheeled Off-the-road vehicles
(10) Development
of space robots and planetary rovers
(11) Development
of omni-directional vehicle and pipe-inspection robots
(12) Driving
actuators, rovers
(13) Development
of omni-directional vehicle and pipe-inspection robots
(14) Driving
actuators, sensors and control of advanced robots
(15) On
Asimovfs three principles for robots (Engineering of Morality)
(16) Robots
and future society (Future industry and human life)
Advanced Course of Mechanical
Vibration
Autumn Semester (2-0-0)
Prof. Nobuyuki IWATSUKI, Prof. Mitsuru ENDO, Prof. Masaaki
OKUMA
[Aims]
The course aims to teach basic concepts and recent
developments related to mechanical vibrations, structural dynamics, acoustics and
vibration control.
[Outline]
1. Vibration of Single-DOF vibration system (Prof. Okuma)
1.1 Importance of mechanical vibration1.2 Undamped single-DOF vibration system1.3 Damped single-DOF vibration system@@1.4 Theoretical and experimental modeling into single-DOF vibration system
@@1.5 Fundamental of vibration suppression techniques
2. Vibration of multi-DOF vibration system (Prof. Iwatsuki)
@@2.1 Modal analysis of two-DOF vibration system
@@2.2 Forced vibration analysis of two-DOF vibration
system
@@2.3 Dynamic absorber
@@2.4 Modal analysis of multi-DOF system
3.@@Fundamentals
of Analytical Dynamics (Prof. Endo)
@@3.1 Introduction
(a) Constraints of mechanical systems, (b) Virtual displacement, (c) Principle of virtual work, (d) D'Alembert's principle@@3.2 Derivation of Lagrange's equation
@@3.3 Application examples of Lagrange's equation
@@3.4 Hamilton's principle
Advance Course on Applied Energy
Engineering
Spring Semester (June
and July) (1-0-0)
Prof. I. Satoh:
[Aims]
The up-to-date problems in the thermal engineering field will
be lectured taking the heat transfer in production and material processing for
instance. Measurement and modeling of heat transfer in the production field,
and the novel method for heat transfer control will be described specifically.
[Outline]
1. Engineering
problems related to the heat transfer
2. Characteristics
of the heat transfer in production, e.g. processing with material melting
3. Measurement
of heat transfer related phenomena in processing
3-1. Visualization of material behaviour
3-2. Temperature measurement of the materials
3-3. Deformation measurement of the materials
4. Modelling
of heat transfer related phenomena in processing
4-1. Modelling of solidification of the material in
mold cavity
4-2. Modelling of material deformation in mold
cavity
4-3. Phenomena occurring on the interface between
the material and mold wall
5. Heat
transfer control for processing
5-1. Method of heat transfer control suitable for
production
5-2. Functions newly developed on the products by
heat transfer control
Advanced Course on Energy Physics
Spring Semester (April) (2-0-0)
Prof. Ken OKAZAKI, Assoc. Prof. Kazuyoshi FUSHINOBU
[Aims]
The aim of this lecture is to teach the energy related
physics and applications, having a broad range of spectrum from micro- to
macro-scale and from the fundamentals to up-to-date issues.
[Outline]
1. Introduction
to energy physics
2. Energy
conversion applications and fundamentals
3. Hydrogen-based
advanced energy systems
4. Physics
and chemistry of plasma
5. Statistical
thermodynamics, fundamentals
6. Transport
phenomena in microsystems
7. Electrochemical
reaction and transport phenomena in fuel cells
Intensive Thermal Engineering
Autumn Semester (2-0-0)
Prof. Ken Okazaki, Assoc. Prof. Seiji Okawa and Assoc. Prof. Shohji
Tsushima
[Aims]
The aim of this subject is to extend the studentsf
understanding of the essential part of thermal engineering, comprehensively.
The classes are given by two or three lecturers according to their specialty.
Opportunity to do exercise will be provided frequently for better
understanding.
[Outline]
1. The
first law of thermodynamics, The second law of thermodynamics, Ideal gas,
Carnot cycle
2. Available
energy (Exergy)
3. Gas
power cycles (Otto cycle, Diesel cycle, Gas turbine, etc.)
4. Vapor
power cycles (Rankin cycle, Heat pump)
5. Basic
concepts of heat transfer; Thermophysical properties
6. Heat
conduction
7. Principle
of convection heat transfer; Forced convection
8. Natural
convection; Heat exchangers
9. Boiling
10. Condensation
11. Radiation
12. Numerical
heat transfer
Thermal Engineering in
Environmental Problems
Autumn Semester (October) (2-0-0)
Prof. Katsunori Hanamura, Assoc. Prof. Shohji Tsushima &
Prof. Shuichiro Hirai
[Aims]
Introduction to energy and
environmental problems in modern civilization based on enormous consumption of
fossil fuel. Emphasis is placed on thermal engineering and fluid dynamical
aspects of efficient utilization of energy and advanced energy conversion
system with electrochemical reaction.
[Outline]
-Introduction to thermal energy
in environmental problems
-Radiation transfer
-Thermal radiation in global
environment
-Energy conversion through
electromagnetic wave
-Global carbon circulation and
greenhouse gas control technologies
-Efficient utilization of energy
-Energy security
-Resources, technologies, and
their status
-Advanced energy conversion
technologies
-Electrochemical systems for
energy conversion
-Fuel Cell
-Secondary Battery
Advanced Course
on Basic Phenomenon of Liquid/Solid Phase Change
Spring
Semester (April and May) (1-0-0)
Assoc. Prof. Seiji Okawa
[Aim]
Transferring phenomenon of thermal energy related to phase change between
liquid and solid is presented, macroscopically and microscopically. The main
points are extracted and explained clearly to help understanding the overview.
Various methods of numerical analysis to solve heat transfer phenomena are
explained, briefly. Applications in engineering field related to transferring
phenomenon of thermal energy as liquid/ solid phase change is also introduced.
[Outline]
Homogeneous and heterogeneous nucleation
Numerical analysis for heat transfer problem
including melting & solidification
Fundamentals of Molecular Dynamics Method
Methods to control freezing of supercooled liquid
Melting and solidification of ice and water using
Molecular Dynamics Method
Measuring method of thermal properties
Permeability and porosity of ice particles as porous
media
Theory and Practice on Analysis and
Design of Linear Control Systems
Autumn Semester (April) (2-0-0)
Assoc. Prof. Masaki Yamakita and
Prof. Masayuki Fujita
[Aims]
In this lecture analysis and controller design of linear
systems, especially robust optimal control design, are discussed for general
graduate course students. Understanding of the contents of the lecture, are
supported by lab. works using a CAD (Matlab).
[Outline]
1. Modeling of dynamical systems
2. Simulation of dynamical systems
3. Properties of linear time invariant systems
4. System identification and model reduction
5. Feedback control and stabilization
6. Feedback control and criterion function
7. Sensitivity functions in feedback systems
8. Modeling uncertainty and robust stability
9. Feedback design via loop shaping
10. Fundamental limitations
11. Feedforward design
Advanced Course of Mechanics of
Materials
Spring Semester (1-0-0)
Prof. Kikuo Kishimoto
[Aims]
This lecture aims to teach basic concepts of the mechanics of
solids, emphasizing on mathematical modeling and energy concept.
[Outline]
-Fundamental equation of continuum solids
-Thermodynamics of solids
-Energy principle
-Inelastic behavior and plasticity
-Damage Mechanics
-Crack Mechanics
Advanced
course of Mechanics of Fatigue and Fracture of Materials
Spring Semester (1-0-0)
Prof. Haruo Nakamura
[Aims]
This course will introduce the mechanics of fatigue,
including low and high cycle fatigues, their influencing factors and initiation
and growth mechanisms. Also taught are the fracture problems, including the
fracture toughness and the fatigue crack growth based on the fracture
mechanics.
[Outline]
- General Explanation of eStrength of
Materialsf
- High cycle fatigue
-
Influencing factors
- Low
cycle fatigue
- Initiation
and growth mechanisms
-
Elementary fracture mechanics
-
Fatigue crack growth
Linear
Fracture Mechanics
Autumn
Semester (1-0-0)
A.Todoroki,
Y. Mizutani
[Aims]
The present course provides
basic understanding of fracture of mechanical engineering structures. The
course deals with the basic mechanics of materials from the definitions of
stress and strain in the first lecture, and it includes outline of the linear
fracture mechanics under the small scale yielding condition. The linear
fracture mechanics is indispensable for mechanical engineers to prevent
failures due to crack growth. Applicants should have attended the Advanced
Course of Mechanics of Materials.
[Outline]
1. Mechanics of Material and Fracture
2. Theory
of elasticity & Stress Intensity factor
3. Crack
Tip Plasticity
4. Fracture
toughness and Fracture toughness test
5. Fatigue
& Stress Corrosion Cracking
6. Structural
integrity evaluation process for a nuclear power plant & Non Destructive
Testing
7. Examination
Special Lecture on Strength of
Materials A, B, C, D
(1-0-0)
[Aims]
The aim of this course is to provide advanced and up-to-date
topics in mechanics of materials. Each lecture is given by distinguished
researcher in some specific field of mechanics of materials from all over the
world. The main target of the course is students who are making researches in
the field of mechanics of materials.
[Outline]
Subjects are selected form current research topics of
strength of materials as follows;
1. Historical
lessons of the failure accidents.
2. Fracture
of solids and materials.
3. Energy
release rate, stress intensity factor.
4. Fracture
toughness and fracture resistance
5. Time
dependent fracture
Intelligent
Control
Spring Semester (April) (1-0-0)
Assoc. Prof. Kurabayashi Daisuke
[Aims]
This lecture aims to teach
fundamentals of intelligent control techniques including artificial neural
networks, fuzzy control and some soft-computing techniques. This lecture also
covers machine learning and searching methods. [Outline]
1. Static and Adaptive systems: High gain system and
gain scheduled method.
2. Non-minimal realization and Adaptive Identifiers
3. Model Referenced Adaptive Control System
4. Stochastic systems and Self-tuning Regulator
5. Fuzzy theory and control
6. Artificial Neural Networks
7. Reinforcement Learning
Computer Vision
Spring Semester (April) (2-0-0)
Prof. Okutomi Masatoshi
[Aims]
In this lecture the characteristics of computer vision system
are explained and the theoretical analysis and controller design are discussed.
Considering a practical usage and actual applications, fundamental technology
related on computer vision systems is introduced.
[Outline]
1. Fundamental
theory of vision.
2. Computer
information technology for vision system
3. Reconfiguring
process of computer visual information
Advanced Course of Fluid Power
Robotics
Autumn Semester (October) (1-0-0)
Prof. Ato Kitagawa & Assoc. Prof. Hideyuki Tsukagoshi
[Aims]
This course will introduce the advantages and the problems of
fluid power control systems from the point of applying them to robotics, after
showing you their basic characteristics and how to design them. Furthermore,
the newly proposed topics to solve the conventional problems will be introduced
by using videos, which are related to fluid power actuators, pressure power
source, and their application such as search & rescue robots and welfare
robots.
[Outline]
1. Characteristics
and how to design of fluid power control system
2. New
topics of fluid power actuator and its control method
3. Pressure
power source
4. Search
& rescue robots
5. Wearable
fluid power
Intelligent
and Integrated Manufacturing
Spring Semester (April) (2-0-0)
(Even Years)
Prof. Yoshio Saito & Assoc.
Prof. Tomohisa Tanaka
[Aims]
The aim of this course is to
extend the understanding of the manufacturing system and to master the
technologies concerning to intelligent and integrated manufacturing. Main part
of production system is the machine tool with numerical control unit that can
be fully integrated by computer control.
[Outline]
1. Concept of production and manufacturing system
2. The role of mechanical and production engineering
3. CAD, CAM, CAE for manufacturing system
4. Computer numerical controlled technology
5. Information technology related production
management engineering
6. Rapid prototyping technology
Advanced Course of Biomechanics
Autumn Semester (December) (1-0-0)
Prof. Norio INOU
[Aims]
Biological shapes, mechanisms, functions and systems are
presented from the view point of mechanical engineering. Bio-robots with
biological characteristics is also introduced
[Outline]
1. Scaling:
Biological shape and function
2. Self-organization
of biological tissue
3. Biological
sensors and the mechanisms
4. Muscles
and musculoskeletal system
5. Cellular
automaton and L-system
6. Bio-inspired
robots
Special Lecture on Mechano-Infra
Engineering A, B, C, D
[Aims]
Interdisciplinary subjects for mechanical and production
engineering in order to master the ability of creative research and development
regarding to the production project
[Outline]
1. Basic
understanding of Mechano-Infra Engineering
2. Concept
of mechanical and production engineering
3. Research
and development in practical field
4. Internship
with Laboratory and Company
Automotive Structural System
Engineering (TAIST)
Spring Semester (3-0-0)
T. Kitahara, H. Morimura, T. Adachi
[Aims]
Vehicle research and development are overviewed, including
planning and design, process from advanced research to the future prospect.
Suspension and driven-train systems are presented with Mechanics of thin-walled
Structures fro automobiles.
[Outline]
1. Overview
on Vehicle Research and Development (15 hours, T. Kitahara)
1.1 Vehicle Planning and Design
(1) From Advanced Research to Marketing
(2) The Past and the Future Prospect
1.2 Vehicle Components
(1) Propulsion, Engine
(2) Body and Suspension
1.3 Vehicle Characteristics
(1) Performance of Man-Machine-Environment System
(2) Active Safety and Passive Safety
2. Suspension
and Drive-train Systems (15 hours, H. Morimura)
2.1 Suspension system
2.2 Steering System
2.3 Tire and its interaction with road
surface
2.4 Braking System
2.5 Friction and tribology
2.6 Drive-train
2.7 Stability and maneuverability analysis
2.8 Advanced Control System
3. Mechanics of Thin-Walled Structures for
Automobiles (15 hours, T. Adachi)
3.1 History
and Design concept of automobile structures
3.2 Automobile
Structures from View of Solid Mechanics
3.3 Fundamentals
of Structural Mechanics
3.4 Mechanics
of Thin-Walled Structures
3.5 Introduction
of Plate Bending Theory
3.6 Absorption
Mechanism of Structural Impact
3.7 Fundamentals
of Dynamic Measurement
Automotive Comfort Mechanics
Engineering (TAIST)
Spring Semester (3-0-0)
M. Yamakita, K. Hanamura, M. Okuma
[Aims]
Automotive comfort mechanics engineering is introduced
through electronic control engineering, aerodynamics, air-conditioning and
vibration noise engineering.
[Outline]
1. Electronics
and Control Engineering (15 hours, M. Yamakita)
1.1 Introduction of electronics and control
in automobiles
1.2 Electric control of engines and
transmission
1.3 Electronics in operation monitoring
1.4 Electric control in braking systems
1.5 Electric control systems for automotive
mobility and safety
2. Aerodynamics
and Air Conditioning (15 hours, K. Hanamura)
2.1 Fundamentals of Fluid-Dynamics
2.2 Computational Fluid Dynamics (CFD)
2.3 Aerodynamics in Vehicles
2.4 Thermodynamics in Air-Conditioners
2.5 Air-Conditioning Systems in Vehicles
3. Vibration
and Noise Engineering (15 hours, M. Okuma)
3.1 Introduction of automotive vibration and
noise problems
3.2 Measurement and data processing for
vibration and noise
3.3 Modelling for vibration and noise
analysis, and comfortability
3.4 Numerical simulation of vibration and
noise
3.5 Structural design and technology for
vibration and noise reduction
Advanced Production Engineering
(TAIST)
Autumn (Summer) Semester (3-0-0)
Y. Saito, K. Takahashi,
H.Umemuro
[Aims]
Fundamentals of production engineering are introduced through
advanced production processes for integrated and intelligent manufacturing
system, advanced welding technologies and quality management.
[Outline]
1. Fundamentals
of Production Technology (15 hours, Y. Saito)
1.1 Production Processes for Automotive
Engineering
1.2 Integrated and Intelligent Manufacturing
System
1.3 Structure and Function of Machine Tools
1.4 Computer Numerical Control of Machine
Tools
1.5 Practical Training of CAD/CAM and CNC
Machine Tools
2. Welding
and Joining (15 hours, K. Takahashi)
2.1 Physics and Basic Engineering in Welding
and Joining
2.2 Welding and Joining processes
2.3 Equipments for Welding and Joining
2.4 Behaviour of Materials in Welding and
Joining
2.5 Design and Construction of Joints
2.6 Analyses of Joints
2.7 Examples of Welding and Joining process
3. Quality
Management and Production Planning (15 hours, H.Umemuro)
3.1 Problem Solving Using SQC tools
3.2 Process Control
3.3 Quality Design by Experimental Study
3.4 Reliability Engineering
3.5 Scheduling Methods
3.6 Inventory Control
Combustion Engineering (TAIST)
Autumn Semester (3-0-0)
S. Hirai, H. Kosaka
[Aims]
Fundamentals of combustion are presented through reactive gas
dynamics and combustion technologies in internal combustion engines.
[Outline]
1. Fundamentals
of Combustion (15 hours, S. Hirai)
1.1 Reactive gas dynamics (laminar and
turbulent flames)
1.2 Ignition and extinction
1.3 Reaction kinetics and simulation
2. Thermodynamics
in Internal Combustion Engines (15 hours, H. Kosaka)
2.1 First and second laws of thermodynamics
in internal combustion engines
2.2 Gas cycles of internal combustion engines
2.3 Thermodynamic analysis of heat release
rate in internal combustion engines
3. Combustion
Technologies in Internal Combustion Engines (15 hours, H. Kosaka or T.
Kamimoto)
3.1 Combustion in spark ignition engine
3.2 Combustion in compression ignition engine
Advanced Internal Combustion Engine
Engineering and Future Power Train (TAIST)
Autumn Semester (3-0-0)
T. Kamimoto, K. Hanamura, K. Okazaki
[Aims]
Flow and combustion diagnostics in IC engines, zero emission
technologies and future energy systems for sustainability is presented from the
point of views of present status and future prospect.
[Outline]
1. Advanced
Combustion Technologies in Internal Combustion Engines (15 hours, T. Kamimoto)
1.1 Advanced technologies for improvement of
thermal efficiency of internal combustion engines
1.2 Advanced technologies for reduction of
emissions from internal combustion engines
2. Zero
Emission Technologies (15 hours, K. Hanamura)
2.1 Production and control of NOx
2.2 Production and control of particulate
matters
2.3 Advanced zero emission technologies
3. Future
Power Train for Sustainable Community (15 hours, K. Okazaki)
3.1 Energy consumption and environmental
protection -Present status in South-East Asia and World-
3.2 Future energy systems for sustainability
3.3 Present status and future prospect of
sustainable mobility
Battery
electrical vehicle, hybrid vehicle, fuel cell vehicle
Basics of Automotive Design (TAIST)
Autumn Semester (3-0-0)
I. Hagiwara, I. Kajiwara, H.
Morimura, M. Okuma
[Aims]
Vehicles are designed using a Computer Aided Design (CAD)
system, including mesh generation and theory of line and curved surface as well
as reverse engineering.
[Outline]
1 Basics
of CAD (15 hours, I. Hagiwara)
1.1 Overview of CAD
1.2 Theory of Curved Line and Curved Surface
1.3 Theory of Mesh Generation
1.4 Theory of Reverse Engineering
2 Basics
of CAE (15 hours, I. Kajiwara)
2.1 Overview of CAE
2.2 Technology for Analysis
(Finite
Element Method, Boundary Element Method, Optimization Analysis, Control
Engineering)
2.3 Application examples
3 CAE
Model (15 hours, H. Morimura, M. Okuma)
3.1 Generating CAE Model from CAD
3.2 Generating CAE Model from Measured DATA
3.3 Generating CAE Model from Experiments
3.4 Identification of CAE Model
Practice of Automotive Design
(TAIST)
Autumn Semester (2-1-0)
H. Morimura, I. Hagiwara
[Aims]
Practice of design of formula car is performed using a
concept of frame structures and analysis of strength and stiffness.
[Outline]
1 Practice
of Design (1) / Design of SAE-Formula Car (15 hours, H. Morimura, I. Hagiwara)
1.1 Planning of Vehicle
1.2 Harmonization of Performance and
Components
1.3 Concept of Frame Structures
1.4 Analysis of Strength and Stiffness with
CAD/CAE
2 Practice
of Design (2) / Analysis of SAE-Formula Car (15 hours, H. Morimura)
2.1 Tuning of Engine Performance and Gear
ratio
2.2 Braking effort and Brake-lock
2.3 Performance of Circling Movements
2.4 Maneuverability
3 Assembly
and Disassembly of Engine and Beam Model (15 hours, H. Morimura)
3.1 Disassembly of Engine and Measurement of
Components
3.2 Assembly of Engine
3.3 Assembly of Miniature Beam Model for
Frame Structure
3.4 Measurement of Beam Model
System Project Research A, B
Seminar in Mechanical and
Production Engineering A,B,C,D
Mechanical and Production
Engineering Off-Campus Project I, II
5.5 Information and Communication
Technology Course
Advanced Electromagnetic Waves
Spring Semester (2-0-0)
Prof. Makoto Ando
Assoc. Prof. Jiro Hirokawa
[Aims]
The objective of this course is to provide the basic
methodology and the interpretation in the boundary value problems of
electromagnetic waves. Some canonical problems in electromagnetic wave
scattering are solved. Important concept of gfield equivalence theoremh is
explained. The following topics are included.
[Outline]
1. Derivation
and interpretation of Maxwellfs equations
2. Linear
differential equations
3. Boundary,
edge and radiation conditions
4. Radiation
from a dipole
5. Solutions
for homogeneous equations
6. Canonical
problems solved by separation of variables
7. Diffraction
from a half plane
8. Diffraction
from a cylinder
9. Direct
integration the field equations
10. Field
equivalence theorem
Wireless Communication Engineering
I
Spring Semester (2-0-0)
Prof. Kiyomichi Araki
[Aims]
The fundamentals in wireless communication engineering, from
wireless channel characteristics to traffic control are to be explained.
[Outline]
1. Wave
Propagation and Scattering
2. Fading
and Shadowing
3. Antenna
and Diversity
4. Space
and Time Signal Processing
5. Modulation
and Demodulation
6. Coding
and Decoding
7. RF
Device
8. RF
Circuit Design
9. Multiple
Access
10. Cryptography
and Security
11. Future
Trends, e.g., Software-defined radio, UWB etc.
Guided Wave Circuit Theory
Spring Semester (2-0-0)
Prof. Tetsuya MIZUMOTO
[Aims]
The lecture is focused on the guided wave theory and its
application to the design of guided wave circuit in microwave, millimeter-wave
and optical frequency regions.
Topics included are electromagnetic wave in waveguides,
dispersion in an optical fiber, coupled mode theory, electromagnetic wave in a
periodical structure, scattering matrix representation, eigen excitation, and
the design of some guided wave circuits.
[Outline]
1. Introduction
to guided wave circuits
2. Electromagnetic
wave propagation in transmission lines
3. Electromagnetic
waves in planar waveguides for microwave and millimeter-wave
4. Eigen
mode of optical planar waveguides
5. Wave
propagation and dispersion in optical fibers
6. Coupled
mode theory
7. Electromagnetic
waves in periodic structures
8. Circuit
representation by a scattering matrix
9. Eigen
excitation and eigen values
10. Design
of couplers and dividers
11. Design
of resonators and multi/demultiplexers
12. Design
of isolators and circulators
Electric Power System Analysis
Autumn Semester (2-0-0)
Prof. Hirofumi Akagi
[Aims]
The aim of this graduate class is to achieve analysis of
electric power systems on the basis of the theory of instantaneous active and
reactive power in three-phase circuits in comparison with conventional
theories. In addition, this class includes applications of the theory to power
electronic equipment.
Note that this graduate class is based on the following two
undergraduate classes: Power Electronics and Electric Machinery.
[Outline]
1. Analytical
methods and basic theories
2. Active
and reactive powers in single-phase circuits
3. Instantaneous
power theory in three-phase circuits
1. Definition of the
instantaneous active reactive powers and their physical meanings
2. Applications of the theory to
power electronics equipment
4. Coordinate
transformation
1. Absolute transformation and
three-to-two phase transformation
2. dq transformation
5. Control
of gird-connected converters for solar-cell and wind-power generation
6. Voltage
and current equation and instantaneous torque of ac machines
7. Instantaneous-torque
control of ac machines
Introduction to Photovoltaics
Autumn Semester (2-0-0)
Prof. Makoto Konagai
[Aims]
This lecture provides descriptions of the basic operating
principles and design of solar cells, of the technology used currently to
produce cells and the improved technology soon to be in operation, and of
considerations of importance in the design of systems utilizing these cells.
[Outline]
1. Review
of semiconductor properties
Crystal
structure, energy bandgap, electrons and holes, doping and Fermi-level, carrier
transport
2. Generation,
recombination, and the basic equations of device physics
Absorption of
light, recombination processes, basic equations of semiconductor devices
3. pn
junction
Carrier
injection, dark characteristics, illuminated characteristics, solar cell output
parameters
4. Efficiency
limits, losses, and measurement
Efficiency
limits, effect of temperature, efficiency losses, efficiency measurement
5. Standard
silicon solar cell technology
Si wafers to
solar cells, solar cells to solar cell modules
6. Improved
silicon solar cell technology
Back surface
field, passivation technology, PERL cell
7. Thin
film solar cells
Amorphous Si,
nano-silicon, Cu(InGa)Se2
8. Other
device structures
III-V compound,
dye-sensitized cell, organic semiconductor cells
9. Photovoltaic
systems: Components and applications
Advanced Electron Devices
Autumn Semester (2-0-0)
Prof. Shunri Oda
[Aims]
On the basis of Electron Devices and Quantum Theory of
undergraduate course, this course provides general consideration on integrated
electron devices leading to advanced discussion on limitation of silicon
microdevices and possibilities of alternative technology.
[Outline]
1. Approaches
for high-speed devices
2. Parameters
which determine the speed of ICs
3. Heterojunction
devices
4. Scaling
limit of MOSFETs
5. Interconnections
6. Physics
of quantum effects in nanoscale devices
7. Criteria
for quantum effects
8. Fabrication
technology of quantum nano-structures
9. Single
electron transistors
10. Josephson
junction and vortex devices
11. Superconducting
digital devices
12. Quantum
computing and architectures
Mixed Signal systems and integrated
circuits
Autumn Semester (2-0-0)
Prof. Akira Matsuzawa
[Aims]
On the basis of Electronic Circuits and Device for under
graduate course, this course provides general consideration on mixed signal
system and its integrated circuit technology which becomes the most important
technology in current electronics. Basic understandings on mixed signal
systems, CMOS circuit design, device technology, and LSI design will be
covered.
[Outline]
1. Mixed
signal systems
2. High
speed A/D and D/A converters
3. Sigma
delta Modulator and A/D, D/A converters
4. Wireless
systems
5. Building
blocks and circuit design for wireless systems
6. PLL
and related systems
Electronic Materials A
Spring Semester (2-0-0)
Assoc. Prof. Shigeki Nakagawa
[Aims]
Electronic properties of solids are lectured based on quantum
mechanics. Beginning with fundamentals of quantum mechanics, perturbation
theory is given as an approximate method. These will be applied to
electromagnetic radiation and energy band theory. Fundamentals of
transportation, scattering and diffraction of waves and particles in solids are
mentioned. Superconductivity and its application to devices are also given.
[Outline]
1. Fundamentals of quantum physics (Review)
2. Time independent perturbation theory -
non-degenerate system -
3. Time independent perturbation theory -
degenerate system -
4. Time dependent perturbation theory
5. Radiation and absorption of photon
6. Energy band theory
7. Fundamental
theory of electric conductivity
8. Scattering
and diffraction of waves and particles
9. Superconductivity
and Meissner effect
10. Josephson's junction & SQUID
Electronic
Materials B
Spring Semester (2-0-0)
Assoc. Prof. Yutaka Majima
[Aims]
On the basis of crystal physics of undergraduate course, this lecture provides fundamentals
of crystallography (lattice and point group), physical tensors (of electricity,
magnetism, elasticity, and optics), lattice vibration, and crystallographic analysis
methodology (X-ray diffraction, electron beam diffraction, SPM, etc).
[Outline]
1.@Crystal
symmetry : Bravais lattice and crystal system, point group, and physical
tensors.
2.@Inverse
lattice and structural analysis:
@@ scattering of waves by crystal, scattering
and Fourier analysis,
inverse lattice
and diffraction condition.
3.@Crystal optics : birefringence and
photoelastic effects,
optical activity
and magneto-optical effects, electrooptic effects, and nonlinear optical
effects.
4.@Elastic properties and wave
propagation in crystals : crystal anisotropy and elastic constants,
elastic
wave equation, anisotropic propagation of elastic waves and its application.
Electronic Materials D
Autumn Semester (2-0-0)
Prof. Mitsumasa Iwamoto
Assoc. Prof. Shigeki Nakagawa
[Aims]
Fundamental theories of dielectric and magnetic properties
are lectured for the better understanding of the materials which are used in
the field of electronics and electrical engineering. After studying how the
polarization, dielectric properties, conductivity and spontaneous magnetization
appear in the materials of organic and inorganic materials, extended theory for
the application of the properties to the future electronic devices are
lectured.
[Outline]
<Fundamentals of electronic properties of organic
materials>
1. Dielectric theory
2. Conductivity,
3. Electronic functions
4. Photo-electronic properties
5. Non-linear optics, etc.
<Fundamentals of magnetism>
6. Magnetic ordering phenomena
7. Magnetic anisotropy
8. Domain structure
9. Magnetization process
10. Spin-dependent
conductivity theory
Physics
and Engineering of CMOS Devices
Spring Semester (2-0-0)
Assoc. Prof. Ken Uchida
[Aims]
This class will overview the operation principle, design guidelines, and
physical phenomena of advanced nanoscale MOS transistors. Particularly, carrier
transport mechanisms in nanoscale MOS transistors and design guidelines for
advanced MOS transistors will be intensively discussed.
[Outline]
1. MOS Capacitor
2. Fundamentals of MOS Transistors
3. Scaling of MOS Transistors
4. Carrier Transport in MOS Transistors 1:
Mobility
5. Carrier Transport in MOS Transistors 2:
High-field Effects
6. Mobility Booster Technologies 1: Stress
7. Mobility Booster Technologies 2: Surface
Orientations
8. Mobility Booster Technologies 3: New
Channel Materials
9. Ballistic Transport
10. Variability
11. Prospects
Topics on Communication Systems Engineering
Spring Semester (2-0-0)
Prof. Yoshinori Sakai
Prof. Kohichi Sakaniwa
Prof. Hiroshi Suzuki
Prof. Tomohiko Uyematsu
[Aims]
Recent topics on communication systems engineering and their
theoretical background will be explained.
[Outline]
1. Bit
Error Rate of Digital Communication Systems
2. Introduction
to Error Correcting Codes
3. Performance
Analysis of Digital Communication Systems Employing Coding
4. Channel
Equalization and Identification: Introduction
5. Adaptive
Channel Equalization Techniques
6. Blind
Channel Identification by Second Order Statistics
(Quiz
for Lectures 4, 5, 6)
7. Image
Coding
8. Video
Coding
9. Multimedia
Communication Technology for the Internet
10. Multipath
Mobile Communication Channels
11. Digital
Modulation Schemes for Mobile Communications
12. OFDM
Mobile Radio Transmission Systems
VLSI Design Methodologies
Spring Semester (2-0-0)
Prof. Hiroaki Kunieda
[Aims]
To master a fundamental knowledge for VLSI design by a
lecture on system, architecture, logic, circuit and layout design with regards
to Large scale Integrated Circuits
[Outline]
1. Digital
Systems and VLSI
2. Transistors
and Layout
3. Logic
Gates
4. Combinational
Logic Networks
5. Sequential
Machines
6. Subsystem
Design
7. Floor
Planning
8. Architecture
Design
9. Chip
Design
10. Supplement
1 Verilog Description for basic components
11. Supplement
2 Verilog Description for registers and state machine
12. Supplement
3 Verilog Description for micro processor
Advanced Signal Processing
Spring Semester (2-0-0)
Prof. Akinori Nishihara
[Aims]
Several important topics on the design and implementation of
signal processing algorithms and their theoretical background will be
discussed.
[Outline]
1. Overview
of Signal Processing
2. Digital
Filter Design
3. Finite
Wordlength Effects
4. Multirate
Systems (Sampling Rate Alteration)
5. Polyphase
Representation
6. Filter
Banks
7. M-channel
Filter Banks
8. Adaptive
Filters
9. Gradient
Adaptive Algorithm
10. Recursive
Adaptive Algorithm
11. DSP
Systems
12. Pipeline
and Parallel Processing
13. Implementation
of DSP Systems
Quantum Information Processing
Spring Semester (2-0-0)
Assoc. Prof. Ryutaroh Matsumoto
[Aims]
Applications of quantum mechanics to communication and
computation are explained. Topics will include quantum teleportation, quantum
cryptography, and quantum algorithms. Prerequisite is linear algebra only. I
will explain mathematics and physics used in the explanation of the above
topics.
[Outline]
1. Mathematical
model of quantum systems
2. BB84
quantum key distribution protocol
3. Tensor
product
4. Quantum
teleportation
5. Superdense
coding
6. Examination
7. Quantum
algorithm for factoring (1)
8. Quantum
algorithm for factoring (2)
9. Quantum
algorithm for factoring (3)
10. Quantum
channel
11. Quantum
error correction
12. BB84
protocol with error correction and privacy amplification
13. Security
analysis of BB84
VLSI System Design
Autumn Semester (2-0-0)
Assoc. Prof. Tsuyoshi Isshiki
[Aims]
This course is designed to cover the underlining theories and
technologies which support the systematic design process of current VLSIs
[Outline]
1. Introduction
- VLSI design methodology and computer-aided design (CAD) tools
2. Introduction
- Hardware description language and hardware behavior model
3. Logic
synthesis - Two-level logic minimization
4. Logic
synthesis - Multi-level logic minimization
5. Logic
synthesis - Area-optimal technology mapping
6. Logic
synthesis - Delay-optimal technology mapping
7. Logic
synthesis - Fan-out optimization
8. High-level
synthesis - Design methodology
9. High-level
synthesis - Operation scheduling
10. High-level
synthesis - Resource allocation
11. Advanced
topics in system-level design issues
Advanced Coding Theory
Spring Semester (2-0-0) Odd Years only
Prof. Eiji Fujiwara
[Aims]
The objective of this course is to introduce an application
of coding theory to digital systems, and to give how to design excellent codes
to improve computer system reliability.
[Outline]
1. Introduction
to Code Design Theory for Dependable Systems
2. Faults,
Errors, and Failures
3. Bit
Error Control Codes: Parity-Check Codes, Hamming Codes, and Hsiao Codes
4. Code
Design Techniques: Odd-Weight-Column Codes, Rotational Codes, etc
5. Mathematics
Necessary to Design Matrix Codes over Extended Field
6. Byte
Error Control Codes: Byte Error Correcting and Detecting Codes
7. Bit/Byte
Error Control Codes: Byte Error Detecting SEC-DED Codes
8. Error
Locating Codes, and Unequal Error Control/Protection Codes
9. Tape
Memory Codes: VRC/LRC, ORC, AXP Codes
10. Magnetic
Disk Memory Codes: Fire Codes, Reed-Solomon Codes
11. RAID
Memory Codes: EVENODD, X-Codes
12. Optical
Disk Memory Codes: CIRC, LDC, RSPC
13. On-Chip
ECCs for Microprocessors
Speech Information Processing
Autumn Semester (2-0-0) (Odd Years)
Prof. Sadaoki Furui
[Aims]
This course aims to discuss various issues related to speech
information processing.
[Outline]
1. Speech
and language
2. Relationships
between various information conveyed by speech
3. Statistical
characteristics of speech signal
4. Speech
analysis methods
5. Speech
analysis-synthesis systems
6. Speech
coding
7. Speech
synthesis
8. Fundamentals
of speech recognition
9. Acoustic
models (HMM and neural networks)
10. Language
models
11. Search,
optimization and adaptation
12. Speaker
recognition
13. Application
of speech information processing technology
Rural Telecommunications
Autumn Semester (2-0-0)
Prof. Jun-ichi Takada
[Aims]
Telecommunications enable the communications instantly
between any points in the world. Moreover, it has become common understanding
that the telecommunication infrastructure is indispensable for the development
of the industry and economy. However, the reality is very severe in the
developing world, especially in rural and remote areas. Imbalance of the
distribution of telecommunications in the world has been intolerable for the
long time. This lecture overviews the historical aspects and the enabling
technologies of rural telecommunications, both in the social and the technical
aspects.
[Outline]
1. Introduction:
Role of telecommunications in the developing areas
2. Historical
overview of the rural telecommunications – gMissing Linkh in 1984
3. Current
status of the rural telecommunications - 20 years after gMissing Linkh
4. Access
infrastructure (1) - Use of amateur radio technology
5. Access
infrastructure (2) - Cellular and personal communication systems
6. Access
infrastructure (3) - Satellite communications
7. Access
infrastructure (4) - TCP/IP based wireless network
8. Access
infrastructure (5) - IEEE 802.11/16/20
9. Access
infrastructure (6) - IEEE 802.22: Cognitive radio
10. Access
infrastructure (7) - Power line communications
11. Information
technology (1) - User terminals
12. Information
technology (2) - Open source for rural telecommunications
13. Case
study taken from ITU-D FG7 database
14. Case
presentations by students (Tokyo Tech)
15. Case
presentation by students (KMITL)
Information and Communication
Technology Off-Campus Project I
Spring Semester
(0-4-0) for
Doctor Degree
Information and Communication
Technology Off-Campus Project II
Autumn Semester
(0-4-0) for
Doctor Degree
[Aims and scope]
Either of above two projects is required for doctoral degree.
The student will take part in an actual project done by an institution or
private company. Project period is from three to six months, in which the
student should work more than 160 hrs in total. Through this internship
projects the student will experience the actual practice in her/his own field
and have proper prospects of her/his future profession.
5.6 Advanced Materials and Chemicals
Processing Course
Advanced Separation Operation
Spring Semester (2-0-0)
Assoc. Prof. Hitoshi Kosuge
[Aims]
Systematic way to count degree of freedom of separation
processes is shown in the first part of this course. Strategy to synthesize the
most feasible separation sequence is introduced with a typical separation task
in the second part. The third part is to show modern separation technologies
including multi-component distillation, extraction and membrane separation.
[Outline]
1. Introduction
2. Fundamentals
of freedom
3. Freedoms
of sub- and complex system
4. Freedom
of distillation tower
5. Separation
sequences and heuristics
6. Evolutionary
synthesis
7. Algorithmic
synthesis
8. Basic
equations in multicomponent distillation
9. Calculation
method of multicomponent distillation
10. Residue
curve map and feasibility of separation
11. Azeotropic
and extractive distillation Process
12. Extraction
Process
13. Membrane
separation process
Transport Phenomena and Operation
for Advanced Materials and Chemicals Processing
Spring Semester (2-0-0)
Assoc. Prof. Shiro Yoshikawa
[Aims]
Momentum, heat and mass transfer in chemical equipment is one
of the most fundamental subjects in chemical engineering field. The methods of
the modeling of the transport phenomena including that in chemical reaction
field are discussed in the course. In addition, the fundamentals of the
numerical analysis are shown.
[Outline]
1. Introduction
2. Basic
equations for transport phenomena (I)
3. Basic
equations for transport phenomena (II)
4. Transport
phenomena in a boundary layer (I)
5. Transport
phenomena in a boundary layer (II)
6. Modeling of transport
phenomena in chemical reaction field (I)
7. Modeling
of transport phenomena in chemical reaction field (II)
8. Numerical
simulation of transport phenomena (I)
9. Numerical
simulation of transport phenomena (II)
10. Characteristics of Particles
11. Motion of Particles in Fluid and Fluid Flow in a
Packed Bed and Fluidized Bed
12. Mechanical Separation and Classification:
Sedimentation, Centrifugation and Filtration
13. Mixing Operation
Fine Particle Engineering
Autumn Semester (2-0-0)
Assoc. Prof. Izumi Taniguchi
[Aims]
There is currently considerable commercial and scientific
interest in the production of fine particles employing aerosol-based methods.
The objective of this course is to provide fundamentals on the behavior of fine
particles in gas phase. In addition, some of recent topics on materials
processing by using aerosol-based method will be presented. Students have to
prepare reading, bring and review the course textbook (Hinds, W. C., gAEROSOL
TECHNOLOGYh, John Wiley & Sons, New York (1999)) to every class.
[Outline]
1. Introduction
2. Topics
of material processing using aerosol-based method (I)
3. Topics
of material processing using aerosol-based method (II)
4. Motion
of a drop or solid particle in gas phase at Rep>2
5. Heat
and mass transfer of a drop or solid particle in gas phase at Rep>2
6. Motion,
heat and mass transfer of a group of drops or solid particles in gas phase at Rep>2
7. Motion
of aerosols (I)
8. Motion
of aerosols (II)
9. Brownian
motion and diffusion in aerosols
10. Coagulation
of aerosols
11. Condensation
and evaporation phenomena in aerosols
12. Aerosol-charging
mechanisms
Chemical Equipment Design and Materials
Autumn Semester (2-0-0)
Assoc. Prof. Masatoshi Kubouchi
[Aims]
The class offers the basic knowledge of the designing method
of cylindrical chemical equipments and materials strength. In addition, recent topics on materials
technology will be presented.
[Outline]
1. Basic
of materials science
2. Basic
of strength of materials
3. Design
of pipe, thermal stress
4. Design
of thin-walled cylindrical vessel for internal pressure
5. Design
of thick-walled cylindrical vessel for internal pressure
6. Design
of external pressure vessel
7. Degradation
of materials
8. Basic
of fracture mechanics
9. Materials
for chemical equipments
10. Other
topics
[Remark]
Students who have already taken or intend to take following
subjects cannot attend this subject.
EgChemical Equipment Design and Materialsh ( undergraduate
subject)
EgAdvanced Chemical Equipment Designh (graduate subject)
Chemical Engineering for Advanced
Materials and Chemicals Processing I
Autumn Semester (2-0-0)
Prof. Masaaki Suzuki, Prof. Kazuhisa Ohtaguchi, Prof. Chiaki
Kuroda and Assoc. Prof. Tetsuo Fuchino
[Aims]
This class covers fundamentals of energy transfer operations,
chemical reaction engineering, and process systems engineering.
[Outline]
1. Introduction
2. Energy
transfer operations (I)
3. Energy
transfer operations (II)
4. Energy
transfer operations (III)
5. Energy
transfer operations (IV)
6. Homogeneous
reactions in ideal reactors (I)
7. Homogeneous
reactions in ideal reactors (II)
8. Flow
patterns, contacting, and non-ideal flow
9. Reactions
catalyzed by solids
10. Process
systems engineering (Analysis) (I)
11. Process
systems engineering (Analysis) (II)
12. Process
systems engineering (Synthesis) (I)
13. Process
systems engineering (Synthesis) (II)
Chemical Engineering for Advanced
Materials and Chemicals Processing II
Spring Semester (2-0-0)
Prof.Masabumi Masuko, Assoc. Prof. Shiro
Yoshikawa, Assoc. Prof. Hitoshi Kosuge, Assoc.Prof. Masatoshi Kubouchi
[Aims]
This class covers essentials of transport
phenomena, separation operations, material science, and thermodynamics.
[Outline]
1. Introduction
Part I Chemical
Thermodynamics
Prof.Masuko
Textbook: P.
Atkins, et al.,"Atkins' Physical Chemistry-7th Ed." Oxford University
Press, Oxford
(2002) Chapt.9.
Reference book: M.
Abbott, et al., "Theory and Problems of Thermodynamics-2nd.Ed."
McGrawhill,
New York (1989) Chapt 7.
2. Chemical Equilibrium Part I
3. Chemical Equilibrium Part II
Part II Material Science
Assoc.Prof.Kubouchi
4. Atomic Structures and Interatomic Bonding, Structures of
Crystalline Solids
5. Phase
Diagrams and Phase Transformations
Part III Mass Transport
Phenomena and Mass Transfer Operations
Assoc.Prof.Kosuge
Textbook: R.Byron
Bird,et.al: gTransport Phenomena 2nd Editionh Wiley New York (2002)
6. Dimension
Analysis
7. Fick's
Diffusion Law, Film Model, Mass Transfer Resistance
8. Multistage
Separation, Separating Agent, Reflux
Part IV Momentum
Transport Phenomena
Assoc.Prof.Yoshikawa
Textbook: R.Byron
Bird,et.al: gTransport Phenomena 2nd Editionh Wiley New York (2002)
9. Newton's
Law of Viscosity and Mechanism of Momentum Transfer
10. Momentum Balance
11. Navier-Stokes Equation and Energy
Balance
Advanced Course in Surface
Properties of Organic Materials
Spring Semester (2-0-0)
Prof. Akihiko Tanioka
[Aims]
Fundamentals and advanced subjects on surface properties of
organic materials will be discussed.
[Outline]
1. Introduction
2. Equilibrium
and non-equilibrium
3. Non-equilibrium
thermodynamics of membrane
4. Membrane
transport phenomena
5. Membranes
(I) - RO and ultra and micro-filtration membranes
6. Membranes
(II) - Ion-exchange membranes
7. Membranes
(III) - Membranes for fuel cell (I)
8. Membranes
(IV) - Membranes for fuel cell (ii)
9. Nan
fibers (I) - Electrospray deposition and electrospinning
10. Nanofibers
(II) - Surface properties
11. Nanofibers
(III) - New aspects of fibers
12. Nanofibers
(IV) - Biosensors and biochips
13. General
conclusions
Advanced Course in Organic
Materials for Photonics I
Autumn Semester (1-0-0)
Prof. Hideo Takezoe
[Aims]
Physics of soft materials will be presented particularly from
the viewpoints of optics and optical properties. Prof. Takezoe will talk about
gPhysics of Liquid Crystalsh.
[Outline]
1. Introduction;
classification of liquid crystals (LCs)
2. Continuum
theory, Defects in LCs
3. LC
displays
4. Phase
transition in LCs, Mean field theory, Phenomenological theory
5. Ferroelectric
LCs
6. Antiferroelectric
LSs and subphases
7. Recent
topics in LCs
Advanced Course in Organic
Materials for Photonics II
Autumn Semester (1-0-0)
Assoc. Prof. Martin Vacha
[Aims]
Physics of soft materials will be presented particularly from
the viewpoints of optics and optical properties. Assoc. Prof. Vacha will talk
about gPhotophysics and Spectroscopy of Organic Moleculesh
[Outline]
1. Quantum
mechanics of the molecule-radiation interaction
2. Excited
state of organic molecules and excited state relaxations
3. Molecular
complexes
4. Intermolecular
photophysical processes
5. External
field effects
6. Principles
of high resolution optical spectroscopy
Advanced Course in Organic and Soft
Materials Chemistry
Spring Semester (2-0-0) (Odd Years)
Prof. Yasuyuki Tezuka, Prof. Masa-aki Kakimoto
[Aims]
Fundamentals and advanced subjects in organic and soft
materials chemistry will be discussed.
[Outline]
1. Introduction
2. Macromolecular
and supramolecular chemistry (I)-- basic principles and concepts
3. Macromolecular
and supramolecular chemistry (II) -- synthesis
4. Macromolecular
and supramolecular chemistry (III) - functions and applications
5. Condensation
polymers (I)-- fundamentals
6. Condensation
polymers (II) -- synthesis
7. Condensation
polymers (III) - functions and applications
8. Topological
polymer chemistry (I) - basic concepts
9. Topological
polymer chemistry (II) -- processes
10. Topological
polymer chemistry (III) - applications and technologies
11. Functional
soft materials (I) - concepts and synthesis
12. Functional
soft materials (II) -- applications
13. General
conclusions
Advanced Course in Wettability
Control of Solid Surface
Spring Semester (2-0-0) (Odd Years)
Assoc. Prof. Akira Nakajima
[Aims]
Wettability has been a research subject at the border between
physics and chemistry, and is an important property of solid surface from both
fundamental and practical aspects. This course provides fundamentals on surface
wettability control for the understanding of surface phenomena and the
designing surface functions of solids. Topics include environmental
purification and energy saving by surface functional materials.
[Outline]
1. Introduction
2. Fundamentals
of solid surface
3. Surface
energy and wettability (I) -- surface energy and its components, measurements
4. Surface
energy and wettability (II) -- surface energy distribution, long range force
5. Surface
structure and wettability
6. Superhydrophilicity
and superhydrophobicity
7. Static
wettability and dynamic wettability (I) -- sliding angle
8. Static
wettability and dynamic wettability (II) -- sliding acceleration
9. Wettability
control by external force
10. Anti-snow
adhesion
11. Materials
for wettability control
12. Coatings
for wettability control
13. Application
to environmental purification and energy saving
Nuclear Materials Science
2008 Autumn Semester (2-0-0) (Even Years)
Prof. Toyohiko YANO
[Aims]
This is the only lecture concerning materials issues,
including nuclear fuels and incore materials, of nuclear fission and fusion
reactors. The basis is materials science. The topics including are:
manufacturing methods of nuclear fuels, structures of fuels and fuel elements,
moderators, control materials, blanket materials, and structural materials.
Another emphasis is put on fundamentals of radiation damage and irradiation
effects of nuclear reactor materials.
[Outline]
1. Components
of LWR, HWR, LMFBR reactors and material selection
2. Radiation
Damage of Materials
3. Physical
and Chemical Properties of U, UO2, and PuO2
4. Fabrication
Process of Nuclear Fuels
5. Fission
and Fusion Reactor Materials
Advanced Chemical Reaction
Engineering
Spring Semester (2-0-0)
Prof. Kazuhisa Ohtaguchi
[Aims]
This course is intended for Chemical Engineering majors.
Pre-request of gChemical Reaction Engineering-1h undergraduate-course
recommended. The objective of this course is to provide a foundation for
mathematical modeling the chemical and biochemical systems in terms of linear
and nonlinear, ordinary and partial, differential equations. The main topics
include: state space analysis; stability of dynamic models, conservation of
mass, pollution in rivers; reaction-diffusion model for morphogenesis; cycles and
bifurcation; cusp catastrophes, and chaos.
Students have to prepare reading, bring and review the course textbook
(Rutherford Aris, gMATHEMATICAL MODELLING TECHNIQUESh, Dover Pub. Inc, (1994))
to every class.
[Outline]
1. Introduction
2. Mathematical
models for the tracer movement in a packed bed
3. The
Taylor diffusion models with laminar flow
4. Models
for the stirred tank reactor
5. A
mathematical model
6. Comparison
of the implications of a model with experience (chaos)
7. The
different type of model
8. Formulation
of a model
9. The
principle of making the equations dimensionless (the stirred tank with a single
first-orderirreversible reaction)
10. The
phase plane analysis
11. Manipulation
of a model into its most responsive form
12. Effective
presentation of a model (catastrophe sets)
13. Models
for diffusion and reaction in a catalyst pellet
Catalytic Process and Engineering
Autumn Semester (2-0-0)
Assoc. Prof. Takashi Aida
[Aims]
The course focuses on the application of catalytic chemistry
and catalytic reactions to the industrial processes, especially to process
intensification through multifunctional reactors.
[Outline]
1. Introduction
2. General
separating reactors
3. Static
separating reactors
4. Introduction
to cyclic separating reactors
5. Chromatographic
reactors (I)
6. Chromatographic
reactors (II)
7. Countercurrent
moving-bed chromatographic reactors (CMCR)
8. Simulated
countercurrent moving bed chromatographic reactors (SCMCR) (I)
9. Simulated
countercurrent moving bed chromatographic reactors (SCMCR) (II)
10. Variation
of CMCR
11. Pressure
swing reactors
12. Temperature
swing reactors
13. Other
separating reactors
Plasma and High Temperature
Processing
Spring Semester (2-0-0) (Even Years)
Prof. Masaaki Suzuki, Assoc. Prof. Hidetoshi Sekiguchi
[Aims]
Characteristics of plasma chemistry, various plasma
generation methods for chemistry and various applications of plasma technology
to chemistry are lectured. Plasma generation methods include thermal
equilibrium plasma; arc plasma, RF plasma microwave plasma and et al. and non
equilibrium plasma; glow plasma, microwave plasma, DBD plasma, and atmospheric
pressure non-equilibrium plasma. Applications of plasma include application of
high temperature heat source, organic and non organic synthesis, decomposition
technology of various materials, separation technology et al. Also current
topics in this field are given.
[Outline]
1. Introduction
2. Basics
of heat transfer in high temperature
3. Basics
of thermal plasmas (I)
4. Basics
of thermal plasmas (II)
5. Numerical
simulation of thermal plasmas
6. Thermal
equilibrium
7. Thermal
plasma processing -Material synthesis (I)-
8. Thermal
plasma processing -Material synthesis (II)-
9. Thermal
plasma processing -Separation-
10. Thermal
plasma processing -Chemical synthesis-
11. Thermal
plasma processing -Wastes treatment-
12. Basics
of non-thermal plasma
13. Non-thermal
plasma processing
Advanced Course in Physical
Properties of Organic Materials
Autumn Semester (2-0-0)
Prof. Toshimasa Hashimoto, Assoc. Prof. Toshiaki Ougizawa,
Assoc. Prof. Masatoshi Shioya, Prof. Takeshi Kikutani, Prof. Norimasa Okui
[Aims]
Physical properties of organic materials are not determined
only by their chemical structures.
Various factors such as the morphology, structure of the crystalline and
amorphous regions, processing history of the method used to form the product
and environmental conditions have significant influences on the physical
properties. This course discusses
various factors influencing the physical properties of organic materials and
fundamentals of the measurement and analysis of the physical properties.
[Outline]
1. Introduction
2. Fundamental
theories for thermal properties of organic materials
3. Analysis
methods of thermal properties for organic materials
4. Morphology
development in polymer alloys
5. Morphology-properties
relationship in polymer alloys
6. Polymer
composites
7. Fundamental
theories for mechanical properties of organic materials
8. Carbon
materials derived from organic materials
9. Crystal
structure of semi-crystalline polymers
10. Crystallization
behavior of semi-crystalline polymers
11. Structure
development in fiber processing
12. Structure
development in polymer processing
13. General
conclusions
Advanced Course of Organic
Materials Design and Characterization
Spring Semester (2-0-0) (Odd Years)
Assoc. Prof. Shigeo Asai, Prof. Masao Sumita
[Aims]
The basic concept for design of functional organic and
polymeric materials and methods to characterize their structure and properties
will be provided.
[Outline]
1. Introduction
2. Concept
for design of functional organic materials
3. Electrical
properties of carbon particle filled polymers
4. Mechanical
properties of fiber reinforced plastics
5. Structure
and properties of multi polymer-filler composites
6. Organic
hybrid materials
7. Intelligent
and future polymeric materials
8. Introduction
to structure analysis of polymer by X-ray scattering
9. Theory
of wide-angle X-ray diffraction
10. Structure
analysis of polymer by wide-angle X-ray diffraction
11. Theory
of small-angle X-ray Scattering
12. Structure
analysis of polymer by small-angle X-ray Scattering
13. General
conclusions
Advanced Course of Polymer
Chemistry
Spring Semester (2-0-0) (Odd Years)
Prof. Akira Hirao
[Aims]
This lecture mainly describes the fundamentals of polymer
syntheses, reactions, and@characterizations. In addition, some of recently advanced
subjects in the related fields are introduced.
[Outline]
1. Introduction
2. Polymer
synthesis (I), step-wise polymerization
3. Polymer
synthesis (II), chain polymerization
4. Polymer
synthesis (III), copolymerization
5. Polymer
reactions
6. Biodegradable
polymers
7. Liquid
crystalline polymers
8. Polymer
structures and characterizations (I)
9. Polymer
structures and characterizations (II)
10. Molecular
design and precise synthesis of polymers
11. Recently
advanced subjects (I), living polymerizations
12. Recently
advanced subjects (II), specially shaped polymers
13. Recently
advanced subjects (III), nano-subjects
Advanced Course in Environmental
Aspects and Porous Materials
Spring Semester (2-0-0) (Even Years)
Prof. Kiyoshi Okada
[Aims]
Various aspects on geo-environmental aspects and porous
materials applicable to these aspects, i.e., preparation methods,
characterization and applications, will be explained.
[Outline]
1. Introduction
2. Geo-environmental
aspects (I) -- energy and atmosphere
3. Geo-environmental
aspects (II) -- water
4. Geo-environmental
aspects (III) -- resources
5. Geo-environmental
aspects (IV) -- ceramic materials
6. Porous
materials (I) -- preparation methods by built up process
7. Porous
materials (II) -- preparation methods by selective leaching process
8. Porous
materials (III) -- characterization
9. Porous
materials (IV) -- porous properties
10. Applications
(I) -- purification of atmosphere
11. Applications
(II) -- purification of waters
12. Applications
(III) -- purification of soils
Nanoscale physics for materials science
Spring Semester (2-0-0)
Prof. Hiroyuki Hirayama, Prof. Takaaki Tsurumi, Assoc. Prof.
Martin Vacha, Assoc. Prof. Tomoyasu Taniyama
[Aims]
This course has been established
within the Global Center of Excellence project (G-COE) as part of a new
graduate education program which provides basic cross-disciplinary concepts in
traditional as well as cutting-edge aspects of materials science and
engineering. The keyword of the course is size-dependence. We are looking at
physical phenomena that undergo a qualitative or quantitative change as the
size of the physical objects decreases. Many of these phenomena are not new;
some of them have been known for the most part of 20th century. Our
goal is to put these phenomena together with the recent developments into a new
perspective. The most dramatic physical changes occur on scales where the
quantum nature of objects starts dominating their properties, i.e. on scales of
0.1 – 1 nm, even though long-range electromagnetic interactions in the regions
10 – 100 nm can be an important factor in many properties. We aim to give
materials scientists and engineers a comprehensive picture of what phenomena
and changes can be expected with downscaling of material objects. In the
treatment we try to avoid as much as possible the traditional division of
materials sciences into inorganic, organic, semiconductor, ceramics,
metallurgical, etc., but rather try to keep the approach general whenever
possible. The course is thus sectioned according to the physical phenomena and interactions. The first part reviews and summarizes the
theoretical background necessary for understanding the following chapters. The
next three parts deal, respectively, with electrical, optical and magnetic
properties as functions of size and distance.
[Outline]
Part 1: Fundamentals of Quantum
Mechanics and Band Structure
1.1 Fundamental of quantum
mechanics
1.1.1 Uncertainty principle: observer
effect, Cauchy–Schwarz inequality
1.1.2
Schrödinger equation: wave function, Hamiltonian operator, eigenstate, principle
of superposition
1.1.3
Matrix mechanics: quantum state vector, normalization, complete system
1.1.4 Perturbation
theory:
1.2 Electronic band structure of
solids
1.2.1 Reciprocal
space: k-vector, Brillouin
zone, energy gap, density of states
1.2.2 Nearly-free
electron approximation
1.2.3
Tight-binding model
1.3 Photonic band structure
1.3.1
Photonic crystals
1.3.2
Propagation of electromagnetic waves in solid: Maxwell's equation, optical
constant
1.3.3 Schrödinger
equation and Maxwell's equation: analogy and difference
1.3.4
Computation of phonic band structure: Plane wave expansion method
Part 2: Electronic states in nanomaterials
2.1 Size effects
2.1.1 Low dimensionality: electronic density of states in 2D,
1D & 0D system, sub-band
formation, quantized conductivity
2.2.2 Quantization: quantum well states in highly symmetric
systems with infinite
confinement; potential barrier, effects of finite barriers, band effects on
quantum well states, numerical methods, quantum well states in low-symmetric
and non-symmetric systems
2.2.3 Edge localized states: Tamm type and Shockley type edge
states, Friedel oscillation
2.2.4 Charging: charging energy, single electron phenomena
2.2.5 Other remarkable effects in nano scales: electron
tunneling, exchange-correlation effects
2.2 Limiting factors in size
effects: thermal broadening and coherence
2.2.1 Thermal broadening: size
dependence of the quantized energy, a comparison of thermal broadening and
quantized energy
2.2.2 Coherence: origins to
break the coherence, electron-phonon coupling and its temperature-dependence
2.2.3 Energy broadening of quantized states: phase
accumulation rule, effects of finite life time on the energy spectrum
2.3 Electronically induced
stable structures in nanomaterials
2.3.1 Closed shell structure: magic
size of clusters, electron closed shell structure
2.3.2 Contribution of quantized
electronic states: electronic growth theory and experiments of atomically flat
ultra-thin metal films, magic thickness commensurate to the Fermi wavelength
Part 3: Optical properties and interactions
3.1 Size-dependent optical
properties: Absorption and emission
3.1.1 Basic quantum mechanics of
linear optical transitions
3.1.2 General concept of exciton
3.1.3 Size effects in high
dielectric-constant materials
3.1.4 Size effects in p-conjugated systems
3.1.5 Strongly interacting p-conjugated systems: a molecular dimer
3.1.6 Molecular Frenkel exciton
3.1.7 Size effects in molecular
excitons - coherence length and cooperative phenomena
3.1.8 Effect of finite number of
optical electrons
3.2 Size-dependent optical
properties: Absorption and scattering
3.2.1 Basic theory of light
scattering
3.2.2 Size-dependent scattering
from dielectric spheres – Mie solutions
3.2.3 Optical properties of
metal nanoparticles - plasmonics
3.2.4 Surface-enhanced Raman
scattering
3.3 Size-dependent interactions:
Particle-particle interactions
3.3.1 Radiative energy transfer
3.3.2 Forster resonant energy
transfer (FRET)
3.3.3 Electron-exchange (Dexter)
energy transfer
3.3.4 Photoinduced electron
transfer
3.4 Size-dependent interactions:
Particle-light interactions
3.4.1 Optical interactions in
microcavities
3.4.2 Effect of dielectric
interfaces
Part 4: Magnetic and magnetotransport properties
4.1 Size and surface effects in
3D confined systems
4.1.1. Quantization of
electronic structures and Kubo effect - parity effect in electron number
4.1.2. Surface magnetism in
transition noble metals
4.1.3. Single domain structures
and superparamagnetism
4.2 Ferromagnetic domain
structures and domain wall related phenomena
4.2.1. Macroscopic quantum
tunneling of domain walls
4.2.2. Electron scattering at
domain walls - quantum coherence
4.2.3. Spin transfer vs.
momentum transfer - current induced domain wall motion
4.3 Spin transport in magnetic
nanostructures – magnetic interface effect
4.3.1. Giant magnetoresistance
(GMR) and tunneling magnetoresistance (TMR) effect - spin dependent scattering
in multilayers and tunneling junctions
4.3.2. Spin accumulation and
current-perpendicular-to-plane (CPP) GMR - spin diffusion length
4.3.3. Spin Hall effect - side
jump and skew scattering due to spin-orbit coupling
Methodologies for Nanomaterials Characterization
Autumn
Semester (2-0-0)
Prof. Hideo Hosono, Prof. Yoshio Nakamura, Prof. Toshikazu
Takata, Prof. Hideo Takezoe, Prof. Junji Watanabe, Dr. Hiroshi Yokoyama
[Aim]
Important
and useful methods for characterizing nanomaterials will be presented. Six
professors will talk their own favorite techniques.
[Outline]
1. Prof. H. Hosono: Photoemission
spectroscopies such as UPS and XPS, and electron spin resonance (ESR)
2. Prof. Y. Nakamura: Electron microscopy
such as transmission electron microscopy (TEM) and scanning electron microscopy
(SEM)
3. Prof. T. Takata: Nuclear magnetic
resonance (NMR)
4. Prof. H. Takezoe: Nonlinear optical (NLO)
spectroscopy
5. Prof. J. Watanabe: X-ray analysis
6. Dr. H. Yokoyama: Scanning probe
microscopy (SPM)
Life Cycle Engineering
Autumn Semester (2-0-0)
Assoc. Prof. Tetsuo Fuchino
[Aims]
To realize the sustainability in the chemical industry,
activities through the lifecycles; plant lifecycle, product lifecycle, process
lifecycle, should be designed to provide PCDA (Plan, Do, Check and Action)
cycle properly, and the integrated information environment through the
lifecycles is indispensable. In this class, the methodology to model the
lifecycle activity is discussed, and on the basis of the model, the lifecycle
safety management issue is considered.
[Outline]
1. Introduction
(Lifecycle engineering perspective of chemical process industry)
2. Problems
in lifecycle, -Case and causality
3. BPR
(Business Process Reengineering) approach
4. Lifecycle
activities of chemical process industry
5. Modeling
lifecycle activities -Necessity and approach
6. Business
model methodology: IDEF (Integrated Definition for Functional model) Family
overview
7. IDEF0
modeling (Syntax, Template, Ontology)
8. IDEF0
modeling (Ontology)
9. IDEF0
modeling practice (I)
10. IDEF0
modeling practice (II)
11. IDEF0
modeling practice (III)
12. IDEF0
modeling practice (IV)
13. Integrated
information environment design (Concept)
14. Integrated
information environment design (Data Model)
Practical Aspect for Legal
Agreement on Technical Issues
Autumn Semester (2-0-0)
Lecturer Rokuro Denda
Topics in Advanced Organic,
Polymeric and Soft Materials
Autumn Semester (2-0-0) (Even Years)
Several Professors
[Aims]
Recently developed advance organic, polymeric materials, such
as light-emitting diodes, field-effect transistors, photoresists, and proton
exchange membranes, will be explained.
[Outline]
1. Introduction
2. Engineering
plastics
3. High
strength and modulus fibers
4. Liquid
crystalline materials
5. Conducting
materials
6. Organic
field-effect transistors
7. Organic
light-emitting diodes
8. Photoresists
9. Plastic
lens
10. Proton
exchange membranes
11. Dendrimers
12. Biodegradable
polymers
Topics
in Advanced Materials and Chemicals Processing I
Autumn Semester (2-0-0) (Even Years)
Topics
in Advanced Materials and Chemicals Processing II
Autumn Semester (2-0-0) (Odd Years)
Several Invited Lecturers
[Aims and scope]
Recent various topics on advanced materials and chemicals
processing will be explained by several invited lecturers from private
companies, universities and institutes.
Chemical Engineering Off-Campus
Project I, II
Materials Science and Technology
Off-Campus Project I, II
Organic and Polymeric Materials
Off-Campus Project I, II
I Spring Semester
(0-4-0) for Doctoral degree
II Autumn
Semester (0-4-0) for Doctoral degree
[Aims and scope]
Either of above two projects is required for Doctoral degree.
The student will take part in an actual project done by a private company or
institution. Project period is from three to six months, in which the student
should work more than 160 hrs in total. The student will experience the actual
practice in her/his own field and have proper prospects of her/his future
profession through this internship projects.
Seminar in Chemical Engineering I-
X
Seminar in Materials Science and
Technology I-X
Seminar in Organic and Polymeric
Materials I-X
I, III Spring
Semester (1)
II, IV Autumn
Semester (1)
V, VII, IX
Spring Semester (2)
VI, VIII, X
Autumn Semester (2)
Academic Advisor