Applied Nuclear Physics. Spring and Summer Credit(s) 1 Ordinary class

Transcription

1 Advanced subject Targeted Code M1800 Subtitle Applied Nuclear Physics Spring and Summer Credit(s) 1 teacher Prof. Yuusuke Uozumi This course will provide an overview of nuclear physics as a basic subject of nuclear engineering and technology. 1. Fundamentals of nucleus and particle 2. Nuclear force 3. Nuclear structure 4. Nuclear reaction (1): type of reactions and scattering 5. Nuclear reaction (2): direct reaction and compound reaction 6. Nuclear reaction (3): Nuclear fission 7. Nuclear reaction experiments Nuclear structure and reaction Lecture As needed Report and examination 1

2 Advanced subjects Targeted Code M1801 Subtitle Radiation Information Processing Fall and Winter Credit(s) 2 teacher Prof. Yuusuke Uozumi Basic knowledge on electronic circuit and ionizin gradiation measurement are needed. Detector pulses from ionizing radiation detectors involve variety of information. This course offers basics of pulse shape processing, signal transmission, and data acquisition to draw information definitely. 1. Signal from radiation 2. Preamplifier 3. Basic filtering technique 4. Pulse transmission 5. Linear amplifier 6. Analog to digital converter 7. Digital counter 8. Principles of process control, basic functional blocks Radiation measurement, pulse, digital Lecture As needed Report and examination 2

3 Advanced Targeted 2 nd year Code M1802 Subtitle Aspects of Nuclear Power Reactor Systems I Teacher Prof. Nozomu Fujimoto n.fujimoto@nucl.kyushu-u.ac.jp Spring Credit(s) 1 It is desired to have the knowledge of reactor physics and nuclear fuel engineering. Lectures offer the outline of nuclear energy production systems, centering on nuclear reactor, more specifically, about the form and properties of power reactors and reactor systems based on reactor physics and engineering. These lectures are provided in order to deepen the knowledge of nuclear reactor systems and their engineering issues, and at the same time, to increase the orientation to a solution of issues including various problems involved in nuclear energy, and cultivate creative thinking. 1. What are nuclear reactor process systems? This is to clarify the definitions of system, process, unit operation, element, etc., in order to help students understand nuclear reactor systems well. 2. Reactor physics and reactor engineering (1) For the understanding of reactor engineering and reactor technology of PWR system and its components. 3. Reactor physics and reactor engineering (2) For the understanding of reactor engineering and reactor technology of BWR system and its components. 4. Reactor physics and reactor engineering (3) For the understanding of reactor engineering and reactor technology of Fast reactor and other reactor system and its components. 5. Reactor safety systems (1) For the understanding of multiple safety systems of PWR and the cultivation of engineering thinking about reactor safety. 6. Reactor safety systems (2) For the understanding of multiple safety systems of BWR and the cultivation of engineering thinking about reactor safety. Style of Class Text and References Reactor physics, reactor engineering, cooling system, thermohydraulics thermal reactor, fast reactor Lecture style, using slides and materials. Investigation report and discussion style are also adopted. J. R. Lamarsh, A. Baratta: Introduction to Nuclear Engineering 3rd Ed. Addison-Welsey Publishing Company, 2001 Learning Consultation Testing, Grading and Make an appointment before coming to the office. Evaluate based upon attendance (50%) and task report (50%). 3

4 Advanced Targeted 2 nd year Code M1803 Subtitle Aspects of Nuclear Power Reactor Systems II Teacher Prof. Nozomu Fujimoto n.fujimoto@nucl.kyushu-u.ac.jp Summer Credit(s) 1 It is desired to have the knowledge of reactor physics and nuclear fuel engineering. Lectures offer the outline of nuclear energy production systems, centering on nuclear reactor, more specifically, about the form and properties of power reactors and reactor systems based on reactor physics and engineering. These lectures are provided in order to deepen the knowledge of nuclear reactor systems and their engineering issues, its effects of environment, and at the same time, to increase the orientation to a solution of issues including various problems involved in nuclear energy, and cultivate creative thinking. 1. Radiation effects on human health Understand fundamentals of radiation, radioactivity and its effects on human. 2. Risk on Nuclear Reactor application Lectures on many kinds of accidents in nuclear reactor system and its effects on environment. 3. Energy and Society Understand the present status of our society from a viewpoints of energy consumption and population. Also discuss the capability of nuclear energy system to solve the energy problems. Style of Class Text and References Reactor physics, reactor engineering, Health physics, Risk of nuclear reactor application, Energy supply system Lecture style, using slides and materials Investigation report and discussion style are also adopted. J. R. Lamarsh, A. Baratta: Introduction to Nuclear Engineering 3rd Ed. Addison-Wesey Publishing Company, 2001 Learning Consultation Testing, Grading and Make an appointment before coming to the office. Evaluate based upon attendance (50%) and task report (50%). 4

5 Advanced subjects Targeted Code M1804 Subtitle Physics of Fusion Reactor Engineering Credit(s) 2 teacher Pending Lectures offer the knowledge for fusion core plasma, basic composition of Tokamak type fusion reactor, mat erials, heat removal and fuel systems in the nuclear fusion reactors. Current status of the development of the fusi on reactor is also explained from the viewpoint of reactor engineering. 1. Introduction (1) Nuclear fusion reactions, necessity of plasma and its sustainment condition (2)Basic concept of TOKAMAK-type fusion reactor system 2. Material for fusion reactor (1)Problems concerning materials in the nuclear fusion reactor (2) Vacuum vessel and structural materials for blanket system (3) Future issues 3. Engineering for heat flow dynamics (1) Heat removal at the blanket and diverter systems (2) Future issues 4. Engineering for fuel system (1)About hydrogen isotopes (2) Recovery, separation of hydrogen isotopes and tritium breeding (3) Future issues Fusion reactor, core plasma, blanket, materials, heat engineering, fuel system Lecture and discussion Need an appointment Evaluate by attendance and report 5

6 Advanced subjects Targeted Code M1805 Subtitle Nuclear Chemical Engineering Credit(s) 2 teacher Pending 原子力システムにおける各種プロセス操作についての化学工学問題を論述する 1. 核燃料サイクルにおける各種プロセス操作についての概論 2. 同位体分離各論 同位体分離の需要 化学的方法と物理的方法 拡散的分離操作と機械的分離操作 3. カスケード理論 カスケードの構成および基礎 理想カスケード 方形カスケード ステップカスケードおよび特殊カスケード 分離作業量と価値関数 4. 再処理プロセス操作 Purex 法 : 脱被覆 溶解 抽出 精錬工程 臨界安全設計 条件 各種再処理法 5. 原子炉炉水管理 イオン交換処理および化学体積制御システム 6. 放射性物質の安全回収処理 浄化システム 7. 核融合炉システムにおける同位体分離 次世代原子炉システム 炉型戦略 Lecture Style 一部ゼミ形式 研究 技術報告書 著書等を抜粋した資料 文献 山本寛 原子力化学工学 日刊工業新聞社 原子炉工学講座 4 培風舘 清瀬量平訳 原子力化学工学第 I~ 第 VII 日刊工業新聞社 等 随時電子メール :kotoh@nucl.kyushu-u.ac.jp 出席 (50%) 課題レポート (50%) 6

7 Advanced s Targeted 1 st year Code M1806 Subtitle Aspects of Nuclear Fuel Engineering I Teacher Prof. Kazuya Idemitsu idemitsu@nucl.kyushu-u.ac.jp Spring Quarter Credit(s) 1 Prerequisite Should have learned thermo dynamics, physical chemistry and reactor physics during undergraduate work. Outline of the Class (educational objectives as a whole, individual learning objective and syllabus plan) The role played by nuclear fuel is very important for nuclear power and nuclear power generation in particular. Nuclear fuel is required to generate a large amount of energy and contains radioactive substances generated at the same time. Furthermore, the environment around its usage is in serious condition because the space is radioactively damaged by mesons and nuclear fission fragments, and it is exposed to radical temperature gradients and high temperatures. In this class, students learn the following in order to acquire basic knowledge of nuclear fuel. Outline of the fuel for power reactors Design of fuel rods Physical-chemical properties of oxide fuel Irradiation behavior of oxide fuel Style of Class Test and References Learning Consultation Nuclear power reactor, atomic fission, fuel, property Lecture style Distribute necessary diagrams Make an appointment before coming to the office. is made by examination and report. 7

8 Advanced s Targeted 1 st year Code IM1807 Subtitle Aspects of Nuclear Fuel Engineering II Teacher Prof. Kazuya Idemitsu idemitsu@nucl.kyushu-u.ac.jp Summer Credit(s) 1 Prerequisite Should have learned thermo dynamics, physical chemistry and reactor physics during undergraduate work. Outline of the Class (educational objectives as a whole, individual learning objective and syllabus plan) The role played by nuclear fuel is very important for nuclear power and nuclear power generation in particular. Nuclear fuel is required to generate a large amount of energy and contains radioactive substances generated at the same time. Furthermore, the environment around its usage is in serious condition because the space is radioactively damaged by mesons and nuclear fission fragments, and it is exposed to radical temperature gradients and high temperatures. In this class, students learn the following in order to acquire basic knowledge of nuclear fuel. In the latter part of this class, students learn the following in order to acquire the knowledge of the behavior of fuel rods, particularly within the reactor Soundness of cladding material and nuclear fuel rod Mechanical properties of oxide fuel Physical-chemical properties of plutonium fuel Irradiation behavior of plutonium fuel Style of Class Test and References Learning Consultation Nuclear power reactor, atomic fission, fuel, property Lecture style Distribute necessary diagrams Make an appointment before coming to the office. is made by examination or report. 8

9 Advanced subjects Targeted S tudents Code M1808 Subtitle Material Science of Non-stoichiometric Compound teacher Prof. Kazuya Idemitsu idemitsu@nucl.kyushu-u.ac.jp Fall and Winter Credit(s) 2 Statistical mechanism, Physical chemistry Non-stoichiometric compounds are chemical compounds those have elemental composition whose proportions cann ot be represented by integers. Non-stoichiometry occurs by point defects in crystal. The degree of non-stoichiometry will be affected by environment such as partial pressure of component element a nd temperature. At the same time the degree of non-stoichiometry affects solid state properties such as electric co nductivity, diffusion coefficient so on. In this class the following topics will be lectured; Basic statistical mechanism, Phase rule, Point defects, Frenkel defects, Order-disorder structure, Electric conductivity change by non-stoichiometry, Oxygen sensor, Coulometric titration. Non-stichiometric compound, Crystal structure, Electric conductivity, Diffusion Lecture style, using slides and other materials. To be introduced in lectures. idemitsu@nucl.kyushu-u.ac.jp Evaluated by examination. 9

10 Advanced subjects Targeted Code M1809 Subtitle Materials science for energy systems I Basic of crystallography Fall Credit(s) 1 teacher Prof. Yasukazu Murakami This class provides an opportunity to learn about the basic of crystallography, which is essential for thorough understanding of the physical/chemical properties of materials related with various energy systems. 1. Introduction 1.1. Relationship between crystallography and materials science for energy systems 2. Basic of crystallography 2.1. Bravais lattice and symmetry operations 2.2. Point group and space group 2.3. International tables for crystallography 2.4. Real space and reciprocal space 2.5. Symmetry of crystals and pattern formation in materials crystal structure, symmetry operation, point group, space group Lecture style, using slides and other materials. To be introduced in lectures , murakami@nucl.kyushu-u.ac.jp Evaluated by examination. 10

11 Advanced subjects Targeted Code M1810 Subtitle Analysis of crystal structure, chemical compo sition, and electronic state Winter Credit(s) 1 Materials science for energy systems II teacher Prof. Yasukazu Murakami Knowledge of Materials science for energy s ystems I Basic of electron diffraction and classical electron microscopy will be explained. Both of these methods are useful in characterizations of materials, particularly on the crystal structure, chemical composition, and electronic state. 1. Analysis of crystal structure using electrons 1.1. Diffraction of light, X-ray, and electrons 1.2. Observations of lattice imperfections 1.3. Imaging of atomic arrangement in crystals 2. Essence of analytical electron microscopy 2.1. Chemical composition 2.2. Electronic state 2.3. Electromagnetic fields in crystals diffraction, crystal structure, chemical composition, electronic state Lecture style, using slides and other materials. To be introduced in lectures , murakami@nucl.kyushu-u.ac.jp Evaluated by examination. 11

12 Advanced Targeted 1 st year Code M1811 Subtitle Radiation Physics and Measurement I Teacher Prof. Keisuke Maehata Spring Credit(s) 1 It is important to utilize the techniques of detection and measurement of radiation such as photons, neutrons and electric charged subatomic particles for investigations of various microscopic phenomena in nuclear engineering, physics, chemistry, biology and medical science. Radiation causes various physical phenomena such as ionizationand excitation of atoms in passing though matter. These physical phenomena are utilized for radiation detection. This lecture deals with the interaction of radiations with matter. The contents of this lecture are listed below. 1. Energy loss of heavy charged particles by atomic collisions 2. Cherenkov radiation 3. Energy loss of electrons and positrons in matter 4. Multiple Coulomb scattering 5. Energy struggling 6. Interaction of photons with matter 7. Interaction of neutrons with matter Style of Class Text and References Learning Consultation Testing, Grading and Radiation measurement, radiation physics Lecture style Select in accordance with the knowledge of students Evaluated by reports 12

13 Advanced Targeted 1 st year Code M1812 Subtitle Radiation Physics and Measurement II Teacher Prof. Keisuke Maehata Summer Credit(s) 1 It is important to utilize the techniques of detection and measurement of radiation such as photons, neutrons and electric charged subatomic particles for investigations of various microscopic phenomena in nuclear engineering, physics, chemistry, biology and medical science. This lecture deals with the detection technique of radiation and typical radiation detectors The contents of this lecture are listed below. 1. General characteristics of radiation detectors 2. Ionization detectors 3. Scintillation detectors 4. Semiconductor detectors 5. Cryogenic particle detectors Style of Class Text and References Learning Consultation Testing, Grading and Radiation measurement, radiation physics Lecture style Select in accordance with the knowledge of students Evaluate by reports 13

14 Advanced s Targeted 1 st year Code M1813 Subtitle High-Energy Nuclear Reaction Teacher Prof. Kenji Ishibashi Fall and Winter Credit(s) 2 Prerequisite Outline of the Class (educational objectives as a whole, individual learning objective and syllabus plan) In recent years, high energy nuclear reaction phenomena have become important in the field of nuclear engineering. Lectures are given on the following as a basis of nuclear engineering: Fermion and boson Quark and lepton Electromagnetic interaction, weak interaction and strong interaction Baryon-decuplet state Baryon-octet state Pseudoscalar meson Vector meson Quantum field theory and Dirac equation Style of Class Test and References Learning Consultation Testing, Grading and Lecture style References: D. H. Perkins, Introduction onto High Energy Physics, Addison-Wesley Pub. (1987) Jo Nakanishi, New Series of Physics 19, Quantum field theory, published by Baifukan is made by attendance, including training (20%), and a report or test (80%). 14

15 Advanced subjects Targeted Code M1814 Subtitle Physics of Liquid Crystals I Credit(s) 1 teacher Pending なし 液晶とは何かに始まり その理解に必要な基礎的物理と最近までの電子工学的応用を講義する 1. 始めに 2. 液晶とは何か 3. 液晶ディスプレーの原理 1 4. 液晶ディスプレーの原理 2 5. 液晶ディスプレーの原理 3 6. 弾性力学 7. 電気光学効果 8. 電気光学効果 9. 液晶ディスプレの駆動法 10. 液晶ディスプレーの駆動法 11. 省エネルギー化法 12. の液晶デバイス Lecture Style: 独自の講義ノートを使い 必要に応じて OHP や板書を行う 教科書はなし References:Liquid Crystals by P.G.deGennes レポートあるいは試験にて 60 点以上取得したものを合格とする 15

16 Advanced subjects Targeted Code M1815 Subtitle Physics of Liquid Crystals II Credit(s) 1 teacher なし 液晶の相構造の定義 強誘電液晶 バナナ液晶 液晶エラストマーの物理学およびそれらの応用について講義する 1. 液晶の物理的定義 2. 液晶の熱力学 3. 相転移 4. 相転移 5. 弾性力学 6. 弾性力学 7. 電気光学効果 8. 電気光学効果 9. 対称性と液晶 10. 強誘電性の発現機構 11. 強誘電性の発現機構 12. 液晶エラストマーの基礎とその応用 Lecture Style: 独自の講義ノートを使い 必要に応じて OHP や板書を行う 教科書はなし References:Liquid Crystals by P.G.deGennes レポートあるいは試験にて 60 点以上取得したものを合格とする 16

17 Advanced subjects Targeted Code M1816 Subtitle Electronic Properties of Solids I Spring Credit(s) 1 teacher Prof. Tatsuya Kawae Should have learned quantum mechanics statistical mechanics solid state physics. Electron in solids show a variety of properties. The lecture offers how they can be understood in term s of simple models. In this class, the basic properties of solids are given. First, students learn the free electron model, where forces between conduction electrons and ion cores are neglected. Then students learn properties of semiconductors and insulators which are determined by energy bands or band gaps, resulting from the interaction of the conduction electron waves with ion cores of the crystal. 1. Electron in metals 2. Free electron model 3. Bloch theory 4. Wave function of electron in a weak periodic potential 5. Energy band and energy gaps 6. Semiconductor and insulator 7. Other insulator; Mott insulator Lecture style is made by attendance and reports. 17

18 Advanced subjects Targeted Code M1817 Subtitle Electronic Properties of Solids II Summer Credit(s) 1 teacher Prof. Tatsuya Kawae Should have learned quantum mechanics statistical mechanics solid state physics. In this class, students learn superconductivity and magnetism, which are the center of recent topics i n condensed matter physics. learn the basic properties of superconductivity, such as electronic and thermal properties of superconductors, flux quantization and Josephson effect. Then, they learn ori gin of magnetic properties in solids, which are explained by quantum mechanics. Finally, current topics on superconductivity and magnetism are introduced. 1. Electronic and thermal properties of superconductivity 2. Type II superconductor and flux quantization 3. BCS theory and Josephson effect 4. High temperature superconductor 5. Magnetism of atoms 6. Ordered magnetic states 7. Metallic magnetism Lecture style is made by attendance and a reports. 18

19 Advanced subjects Targeted Code M1818 Subtitle Quantum Physics Spring and Summer Credit(s) 2 teacher Prof. Tatsuya Kawae Should have learned quantum mechanics statistical mechanics solid state physics. Lectures are given on current topics of condensed matter physics. 1. Superfluid 4He 2. Normal 3He; Fermi liquid 3. Superfluid 3He 4. S-wave superconductor 5. Superconductor with unusual properties 6. Solid at low temperatures 7. Magnetism in insulators 8. Magnetism in metals Lecture or seminar style is made by attendance and reports. 19

20 Advanced subjects Targeted Code M1819 Subtitle Experimental Practice on Nuclear Engineering Neutron moderation and diffusion in non-multiplying system Through whole a year Credit(s) 2 teacher Prof. Yuusuke Uozumi, Prof. Keisuke Maehata, Prof. Naoko Iyomoto, Prof. Nobuhiro Sigyo, Prof. Hideaki Matsuura This course consists of a series of lectures, practices of computer simulations and experiments to understand the basics of nuclear reactor physics. Lectures cover nuclear physics, neutron physics and radiation measurement technique. In practice of computer simulation, students will learn how to use Monte Carlo Simulation codes. In experiment, neutron flux is measured in a uniform non-multiplying system for neutron moderation and diffusion without fissile isotopes. The experimental results will be compared with the computer simulation. Radiation measurement, pulse, digital processing Lecture,Practice, Experiment As needed Report and attendance 20

21 Advanced subjects Targeted Code M1820 Subtitle Numerical Simulation for Radiation Engineering teacher Prof. Hideaki Matsuura Prof. Nobuhiro Shigyo Spring and Summer Credit(s) 1 Lectures offer opportunity to student for understanding major simulation codes in the radiation engineeri ng field. The purpose of this subject is to learn physics of nuclear radiation and how to use the related si mulation codes. The students make simulations using the typical codes by themselves and evaluate the neu tron flux and energy spectra in the simple nuclear systems. 1. Introduction 2. Outline for simulation codes for nuclear radiation 3. About UNIX System 4. Practice using particle and heavy ion transport code system (PHITS) 5. Practice using Monte Carlo Neutron and Photon Transport Calculation code (MVP) Lecture and Practice Manual for PHITS, Manual for MVP Need an appointment Evaluate by attendance and report 21

22 Advanced subjects Targeted Code M1821 Subtitle Fundamentals of Nuclear Energy Conversion teacher Spring and Summer Credit(s) 2 Pending エネルギーとは何か エネルギー変換とは何か? どのような種類があるか? 個別現象の理解と応用は進められているが 共通する基本原理の理解と体系化は進展中の段階である 学問の現状について述べ エネルギー変換について俯瞰的に理解することを目標とする その上で個別の重要なエネルギー変換のいくつか ( 熱サイクル 熱電変換 MHD 発電 燃料電池 太陽電池 ) について概要を説明する エネルギー変換について原子核エネルギーを例として 熱力学の第一 第二法則の観点から述べ その中でエクセルギーの重要性について説明する 次いで エネルギー変換の種類として スウィング サイクル 直流的結合について説明し 非平衡熱力学の観点から議論を展開する 特に エントロピー生成速度極小の原理のエネルギー変換における重要な役割について説明する いくつかの個別のエネルギー変換について説明し 共通する基本原理を確認する 1. 原子核エネルギー : 発生から電気に至るまで ( ランキンサイクル ) 2. 熱エネルギーの変換 ( 熱力学の第二法則 ) 3. 流動エネルギーの変換 ( 開いた系のエネルギー変換 ) 4. 化学エネルギーの変換 ( エクセルギー変換 ) 5. 未来のエネルギー変換技術に向けて ( 直接エネルギー変換 ) 講義 プリントを配布する レポートを課す 22

23 Advanced Targeted 2 nd year Code M1822 Subtitle Physics Sciences and Engineering of Organic Materials I Spring Credit(s) 1 Teacher Prof. Kazuhiro HARA Prerequisite Outline of the Class (educational objectives as a whole, individual learning objective and syllabus plan) Lectures are given on basics of environmental sciences and engineering related to material and energy balance with an emphasis on organic materials. The Fundamentals of Design Measures of Pollution Pollution Prevention Conservation of Mass Solving Systems of Equations Material Balance with Chemical Reactions The Unsteady-State Material Balance Water Conservation and Reuse Accounting for Energy The Energy Balance and Enthalpy Energy Conservative Design Related Topics Style of Class Text and References Learning Consultation Testing, Grading and Lecture or seminar style Text book:pollution Prevention and Control- Part II Material and Energy Balances by Paul Mac Berthouex and Linfield C. Brown Need an appointment Evaluate by report presentation and/or examination 23

24 Advanced Targeted Code M1823 Subtitle Physics Sciences and Engineering of Organic Materials II Teacher Prof. Kazuhiro HARA Summer Credit(s) 1 Prerequisite Outline of the Class (educational objectives as a whole, individual learning objective and syllabus plan) Lectures are given on basics of environmental sciences and engineering related to material and energy balance with an emphasis on organic materials. The Fundamentals of Design Measures of Pollution Pollution Prevention Conservation of Mass Solving Systems of Equations Material Balance with Chemical Reactions The Unsteady-State Material Balance Water Conservation and Reuse Accounting for Energy The Energy Balance and Enthalpy Energy Conservative Design Related Topics Style of Class Text and References Learning Consultation Testing, Grading and Lecture or seminar style Text book:pollution Prevention and Control- Part II Material and Energy Balances by Paul Mac Berthouex and Linfield C. Brown Need an appointment Evaluate by report presentation and/or examination 24

25 Advanced Specialized Targeted 1 st year Code M1825 Subtitle Nuclear Reaction and Accelerator Slowing-down and diffusion of neutrons Teacher Professor Nobuo Ikeda Spring and Summer Credit(s) 2 Lectures offer the basics of nuclear reaction theory, that is, the basics of nuclear engineering and the basic concept of an electron accelerator indispensable for research of nuclear reactions. This subject also refers to the most advanced technologies of nuclear reaction and electron accelerator. 1. Types of nuclear reactions 2. Kinematics and cross section 3. Elastic scattering 4. Resonance reaction 5. Acceleration and deflection 6. DC electron accelerator and AC electron accelerator 7. Linear accelerator and circular accelerator 8. Nuclear reaction and the most advanced electron accelerator Style of Class Text and References Learning Consultation Testing, Grading and Nuclear reaction, electron accelerator Lecture type Test: None References: Nuclear Physics by Kosuke Yagi, published by Asakura Shobo Introduction to Nuclear Physics by Yoshio Washimi, published by Shoka-do Theory of Nuclear Reactions by Koji Kawai and Shiro Yoshida, published by Asakura Shoten Accelerator Science by Toru Kamei and Motoo Kihara, published by Maruzen As needed Evaluate by the attendance to class and report. 25

26 Advanced Specialized subjects Targeted Code M1826 Subtitle Beam Science Spring and Summer Credit(s) 2 teacher Prof. Nobuo Ikeda Accelerators play important roles in modern medicine, industry, environmental issues, space science, and so on. L ectures offer fundamentals on principal, design, application of the accelerators and frontiers of accelerator science. 1. What is acceleration? 2. Theory of special relativity and particle motion 3. Method of acceleration; DC and AC accelerations 4. Method of acceleration; straight accelerators 5. Method of acceleration; circular accelerators 6. Transport of a beam 7. Storage of a beam 8. Beam collider 9. Application of accelerators: industry and medicine: 10. Application of accelerators: analysis of materials, synchrotron light 11. Application of accelerators: accelerator complex, accelerator frontier 12. Application of accelerators: accelerator driven system, nuclear transmutation, new energy system Lecture type Distribute necessary diagrams Evaluate by the attendance to class and report. 26

27 Advanced Specialized subjects Targeted Code M1827 Subtitle High Resolution Radiation Spectroscopy Fall and Winter Credit(s) 2 teacher Prof.Naoko Iyomoto 放射線分光による元素分析の原理の理解と 精密分光器であるマイクロカロリメータの動作原理 製作方法 読み出し方法などの理解を目標とする マイクロカロリメータの動作原理 電気的 熱的応答 最適フィルタ法による信号処理 超伝導転移端 (TES: Transition-Edge Sensor) 型マイクロカロリメータの製作技術 信号多重化読み出し技術などを テキストに沿って講述する Lecture style and partially seminar style Text : "Cryogenic Particle Detection", Christian Enss (Ed.), Springer References 参考資料等 : 必要に応じて関連した原著論文などを紹介する Evaluate by the attendance to class and report. 27

28 Advanced Specialized subjects Targeted Code M1828 Subtitle Fusion Plasma Science Fall and Winter Credit(s) 2 teacher Prof. Hideaki Matsuura なし Lectures offer the knowledge about principle of plasma physics, basic phenomena in the thermonuclear plasm a, general physics concerning collision and nuclear reaction and the method of the analysis. understand the role of the kinetic equations in the plasma science field and practice the method to solve the equations. 1. Introduction 2. Kinetic equations for plasmas 3. Boltzmann equation 4. Derivation of Fokker-Planck equation 5. Numerical method to solve the differential equations 6. Practice to obtain the ion velocity distribution functions in the thermonuclear plasmas by solving Fokker-Planck equation Lecture and practices G.I.Bell & S.Glasstone Nuclear Reactor Theory Krieger Pub. (1970). F.F.Chen, Introduction to Plasma Physics and Controlled Fusion Springer (1983). Need an appointment Evaluate by attendance and report 28

29 Advanced Specialized subjects Targeted Code M1829 Subtitle Advanced Nuclear Reactor Physics with Experimental Practice Spring and Summer Credit(s) 2 teacher Prof. Hideaki Matsuura, Prof. Tatsuya Matsumoto, Prof. Tatsumi Arima It is desirable to have the knowledge of nuclear reactor physics On the basis of the knowledge for nuclear reactor physics, experimental study to understand fission reactions, n eutron flux, slowing down/diffusion of neutrons in the fission reactors, neutron multiplication, and criticality is per formed using Kyoto University Critical Assembly (KUCA). Experiments (1) Approach to Criticality (2) Control Rod Calibration (3) Measurement of Reaction Rate (spatial distribution of neutron flux) Nuclear Reactor Physics, Critical Assembly Lecture and experiments T. Misawa, et al., Nuclear Reactor Physics Experiments, Kyoto University Press (2010). Need an appointment Evaluate by attendance and report 29

30 Advanced Specialized subjects Targeted Code M1830 Subtitle Fundamental Aspects of Nuclear Fuel Cycle Fall and Winter Credit(s) 2 teacher Prof. Yaohiro Inagaki Desirable to have knowledge on physical chemistry, radiochemistry and reactor physics. The lecture offers outline of nuclear fuel cycle with details of each constituent process, such as reproces management of nuclear waste, on the basis of fundamental knowledge on physical chemistry, radiochemistry an The following subjects are lectured and discussed in the class. 1. World outlook on energy resources and consumption 2. Outline of nuclear fuel cycle 3. Upstream of nuclear fuel cycle 4. Downstream of nuclear fuel cycle 5. Reprocessing of spent nuclear fuel 6. Management of nuclear waste Nuclear fuel cycle, reprocessing, nuclear waste management Lecture or seminar style Nuclear Fuel Cycle Science and Engineering, edited by I.Crosslamd, Woodhead Publishing(2012). The Nuclear Fuel Cycle from ore to waste, edited by P.D.Wilson, Oxford Science Publications(1996). Nuclear Chemical Engineering, M.Benedict, T.H.Pigford, H.W.Levi, McGraw-Hill(1981). Need an appointment inagytne@mbox.nc.kyushu-u.ac.jp Evaluated by examination, report and presentation. 30

31 Advanced Specialized subjects Targeted Code M1831 Subtitle Radiation Effects in Condenced Matter Radiation effects in Nuclear Materials Fall and Winter Credit(s) 2 teacher Prof. Kazuhiro Yasuda High energy particles in crystals lose their energy either through elastic or inelastic interaction. This lecture deals with particle-solid interaction from fundamental point of view. Change in properties in nuclear reactor and fusion reactor is also a subject in this lecture. 1. Introduction 2. Elastic interaction and energy loss 3. Inelastic interaction and energy loss 4. Stopping power and range of ions 5. Point defects and extended defect clusters 6. Models and evaluation of displacement damage 7. Displacement cascade and thermal spike 8. Comparison of radiations with neutron, ion, electron, gamma-ray 9. Kinetics of point defects 10. Radiation effects in metals and alloys 11. Radiation effects in ceramics 12. Ion beam analysis of materials Lecture Style Hand out will be delivered. Reference books are noticed in the class. After classes, or anytime Grading will be done by the attendance in the class and the evaluation of report. 31

32 Advanced Specialized subjects Targeted 2nd year Code M1832 Subtitle Diffraction Physics and Structure Analysis Spring and Summer Credit(s) 2 teacher Prof. Syo Matsumura X-rays, electrons and neutrons behave as waves, and the diffraction by atoms or molecules is widely utilized for experimental determination of their configurations, namely the crystal structure analyses. This lecture will treat the principles of the diffraction of X-rays, electrons and neutrons as the basic knowledges for the structure determinations of crystalline materials. 1. Introduction 1-1 Generation of X-rays 1-2 Electron microscopes 2. Principle mechanisms of scattering 2-1 X-ray scattering with an electron and an atom 2-2 Electron scattering and the atomic scattering factors 2-3 Neutron scattering 3. Diffraction by crystals 3-1 Bragg's law and Laue's law 3-2 Diffraction function and the crystal structure factors 3-3 Reciprocal lattices and Ewald construction 3-4 Crystal structure factors and the forbidden rules 3-5 Effects of outer shapes of crystallites 3-6 Integrated intensities 3-7 Measurement of lattice constants 3-8 Temperature factors X-ray diffraction,electron microscopy, neutron diffraction Lecture Style References "X-ray diffraction" by B.E. Warren (Dover reprint 1990) "Transmission Electron Microscopy" by D.B. Williams,C. Barry Carter (Plenum) Office Room 837, West #2 Phone , syo@nucl.kyushu-u.ac.jp Evaluate with the final examination 32

33 Advanced Specialized subjects Targeted Code M1833 Subtitle Radiation Safety Engineering Fall and Winter Credit(s) 2 teacher Prof. Kenji Ishibashi 原子炉や粒子加速器に関わる放射線の挙動について 下記項目の授業を行う 1. 放射線の遮蔽 (1) 中性子の輸送 (2) 中性子の遮蔽 (3) ガンマ線の輸送 (4) ガンマの遮蔽 2. 環境量子線 (1) ガンマ線 (2) ラドンの挙動 (3) 宇宙線 Lecture Style References 兵藤知典 放射線遮蔽入門 産業図書 (1979) 中性子遮蔽設計法 WG 編 中性子遮蔽設計ハンドブック 日本原子力学会 (1993) 授業出席状況 ( 演習を含む )2 割 レポートまたは試験 (8 割 ) の比率で成績の評価を行う 33

34 Advanced Specialized Targeted 1 st year Code M1834 Subtitle Multiphase Flow Science in Energy Engineering Teacher Assoc. Prof. Koji Morita Spring Credit(s) 2 Nothing particular Multilayer flow is the condition where substances of different phases of solid, gas and liquid are mixed and flow, interacting with others. It is in the form of gaseous and solid, solid and gaseous, solid and liquid and liquid liquid two phase flows. It is often important flow phenomena in engineering, and detailed research about numeral analytical models and calculation methods has been conducted In this class, after learning the basics of multilayer flow phenomena and its numerical analysis method, students deepen the understanding of multiphase flow at a severe accident of a nuclear reactor and its simulation technology. Basics of multiphase flow 1. What is multiphase flow? 2. Form of multiphase flow 3. Physical quantity describing multiphase flow Numerical analysis of multiphase flow 1. Numerical analysis model 2. Basics of finite difference solution 3. Basics of numerical solution Nuclear reactor safety analysis and multiphase flow phenomena 1. Thermal flow numerical analysis of nuclear reactor systems 2. Multiphase flow phenomena at a severe accident of a nuclear reactor 3. Numerical simulation of a severe accident of a nuclear reactor Style of Class Text and References Learning Consultation Testing, Grading and Lecture type, using printed materials and viewgraph As needed, via Evaluate based upon attendance and report 34

35 Advanced Specialized subjects Targeted Code M1835 Subtitle Complex Systems Science Fall and Winter Credit(s) 2 teacher Prof. Hirotaka Okabe Knowledge of the department level mathematics, and computer programming The concept of complex system becomes more important in both the natural and social sciences. However, there is no concise definition of a complex system, let alone a definition on which all scientists agree. Usually, a complex system is a system that exhibits some of the following characteristics; feedback loops; some degree of spontaneous order; robustness of the order; emergent organization; numerosity; hierarchical organization. Because of the diversity of complex systems, we focus the system driven by non-linear dynamics in this class. We lean the basic concepts of complex systems including non-linear dynamics, bifurcation, and the followings. 1) Non-linear spring 2) Chaos 3) Soliton 4) Pattern The computer calculation of some mathematical model will be scheduled according to the students backgro und. complex system, non-linear dynamics, chaos Lecture (and computer programming exercise) type, using pdf and printed materials. Lecture by original stuff Need an appointment Evaluate by the class-end examination or report. The 60% attendance is needed for the evaluation. 35

36 Advanced Specialized subje Targeted cts Code M1836 Subtitle Supermolecular System Science Fall and Winter Credit(s) 2 teacher Prof. Hirotaka Okabe Knowledge of the department level physics, and basic chemistry Supermolecule is a molecular complex which has non-covalent interaction and unique characteristics. Crown ether is a typical example of supermolecule, and supermolecule in chemical field becomes more important. Supermolecule is also used in biochemistry to describe complexes of biomolecules, such as peptides and oligonucleotides composed of multiple strands. This class provides the basics of supermolecule and the concepts of its application. Lecture or seminar style Lecture by original stuff Need an appointment Evaluate by the class-end examination or report. The 60% attendance is needed for t he evaluation. 36

37 Advanced Specialized subjects Targeted Code M1837 Subtitle Statistical Physics teacher Pending Fall and Winter Credit(s) 2 学部の 量子力学 や 熱統計力学 を履修していること ( 全体の教育目標 ) 種々の物理系における相転移点近傍での挙動 ( 臨界現象 ) には多くの類似性が見られる その典型的な例が 流体における気体 - 液体転移と磁性体における常磁性 - 強磁性転移である この講義では 統計物理学の重要な適用対象であるこのような臨界現象の基礎的重要事項や解析方法ならびに最近の知見までを 主にスピン系 ( 磁性体 ) を例に系統的に理解することを目標とする ( 個別の学習目標と授業計画 ): 以下の各項目を数回づつに渡って講義する 1. 臨界現象とは 2. 熱力学的関係式 3. 臨界指数と普遍性 4. 協力現象の古典論 ( ランダウ理論と分子場理論 ) 5. 種々のモデルと厳密解 ( 転送行列法 級数展開法 etc.) 6. スケール仮説と繰り込み群理論 7. 計算機シミュレーション スピン系 相転移 臨界現象 ランダウ理論 繰り込み理論 スケーリング則 教科書を用いての輪講 または必要に応じて OHP や板書によるノート講義 StatisticalMechanicsofPhaseTransitions byj.m.yeomans(clarendonpress) LecturesonPhaseTransitionsandtheRenormalizationGroup byn.goldenfeld (Addison-WesleyPublishingCompany) 統計物理 川村光著 ( 丸善 ) 随時 講義終了時にレポートを課す 全講義回数の 2/3 以上に出席し 平常点とレポート内容が共に評価 60 点以上を合格とする 37

38 Advanced Specialized subjects Targeted Code M1838 Subtitle Applied Condensed Matter Physics Fall and Winter Credit(s) 2 teacher Prof. Satoru Tanaka 量子論 熱統計力学 固体物理学に関する基 礎知識 表面 界面は現在用いられている様々な半導体デバイスにおいて非常に重要な役割を果たしている. デバイスの高性能化 高機能化のためには原子レベルの表面 界面構造制御, 物性制御が不可欠となっている. これら固体表面 ( 界面 ) における様々な物理的 化学的現象はその 2 次元性のために, いわゆるバルク的な性質とは異なり, 得意なものとなる. 本講義では, 固体表面に関する基礎的な内容 ( 構造, 電子状態, 動的過程 ) の理解, さらに応用として表面解析手法, 半導体結晶成長等に関しての知識を得ることを目的とする. 具体的な内容としては, 次の通りである. 1. 表面とは何か? 2. 表面構造 3. 表面の電子状態 4. 表面の動的過程 5. 表面の研究 ( 分析 ) 手法 6. 表面の応用分野 半導体, 表面構造, 表面分析, 結晶成長, エピタキシー, 電子 光デバイス ノート講義 または適当な References に基づく授業 表面科学入門 小間篤ら著, 丸善 PhysicsatSurfaces A.Zangwill,Cambridge 随時オフィス ( ウエスト 2 号館 940 号室 ) にて. stanaka@nucl.kyushu-u.ac.jp ノート持ち込みの試験 あるいはレポート ( プレゼンテーションを含む ) の評点評価 38

39 Advanced Specialized subjects Targeted Code M1839 Subtitle Nuclear Energy Systems and Safety teacher Pending Fall and Winter Credit(s) 2 なし Course Learning Goals / Objectives: 1. To introduce the students to the advantages and disadvantages of nuclear power compared with other energy solutions. 2. To introduce the students to the fundamental principles of nuclear engineering. These topics include atomic and nuclear physics, isotopes and radioactivity, nuclear reactions, fission and fusion, fission chain reaction, reactivity; thermodynamics. 3. Introduction to nuclear safety and design principles. 4. In addition to light water rectors the CANDU, Gas Cooled Reactors and Liquid Metal Fast Breeder reactors design will be introduced. 5. Introducing discussion of Generation II (current) and Generation III, IV (future nuclear) nuclear power plant s. Lecture type (1) Fundamentals of Nuclear Science and Engineering, J. Kenneth Shultis and Richard E. Faw, Marcel Dekker, Inc., ISBN: , 2002 (2) Introduction to Nuclear Engi neering, 3rd Ed., John R. Lamarsh & Anthony J. Baratta, Prentice Hall, ISBN , 2001 (3) Nuclear Energy: An Introduction to the Concepts, Systems, and Applicati ons of Nuclear Processes, 6th Ed., Raymond L. Murray, Butterworth-Heinemann, ISBN: , 2009 Evaluate by the attendance to class and report. 39

40 Additional Specialized subjects or Cross-disciplinary Courses Targeted Code M1843 Subtitle Beam science Fall and Winter Credit(s) 2 単位 teacher Prof. Nobuo Ikeda Electron and Ion beams are widely used in various fields. Advance of beam application is indeed remarkable in medicine and industry. Lectures offer fundamental knowledge in the field of beam science. 1. Interaction of radioactivity with material 2. Concept on radiation dose 3. Radiation and human health 4. Motion of charged particle in magnetic field 5. Time of flight of particles 6. Nuclear decays 7. Measurement of gamma-ray and beta-ray. 8. Behavior of neutron in material and neutron measurement 9. Nuclear Reactor 10. Medicine and Tomography 11. Industry 12. Radiation in space Lecture type Distribute necessary diagrams Evaluate by the attendance to class and report. 40

41 Additional Specialized subjects Targeted or Cross-disciplinary Courses Code M1844 Subtitle Advanced Nuclear Safety Engineering Fall and Winter Credit(s) 2 teacher Prof. Koji Morita In this class, aiming to understand the structure to safety ensuring of nuclear facilities based on the concept of "defense in depth" systematically, the following items relevant to the safety of nuclear facilities will be lectured: 1. basic concept for safety ensuring 2. structure of safety ensuring 3. basic concept of safety design 4. safety facilities of nuclear reactor 5. basic concept of safety assessment 6. risk analysis of accidents 7. examples of severe accidents 8. recent nuclear safety regulation nuclear reactor, safety design, safety assessment Lecture type, using printed materials and viewgraph Reference materials: 1) J.R. Lamarsh, A.J. Baratta, Introduction to Nuclear Engineering, Prentice-Hall, ) B.R. Sehgal, "Nuclear Safety in Light Water Reactors: Severe Accident Phenomenology", A cademic Press, ) G. Petrangeli, "Nuclear Safety", Butterworth-Heinemann, ) A.E. Waltar et al.,risk and Safety Analysis of Nuclear Systems, John Wiley & Sons, As needed, via Evaluate based upon attendance and test 41

42 Additional Specialized subjects Targeted or Cross-disciplinary Courses Code M1845 Subtitle Nuclear Fuel Cycle Experiment I teacher Prof. Kazuhiro Yasuda, Prof. Yaohiro Inagaki, Prof. Tatsumi Arima, Prof. Satoru Yoshioka Spring and Summer Credit(s) 1 This class deals with four themes of experiments and exercise which relates to nuclear fuel cycles, from the sta nd point of materials science. Experiments and exercise will be done by a group with several students. 1. Lecture of nuclear fuel cycle and the relationship with planned experiments and exercise 2. Sintering and structural analysis of oxide ceramics (Yoshioka) 3. Principle of transmission electron microscopy (Yasuda) 4. Extraction solvent (Arima) 5. Materials corrosion (Inagaki) manual of experiments and practices Evaluate based upon attendance and report 42

43 Additional Specialized subjects Targeted or Cross-disciplinary Courses Code M1846 Subtitle Nuclear Fuel Cycle Experiment II Fall and Winter Credit(s) 1 teacher Prof. Koji Morita, Prof. Satoshi Fukada, Prof. Kenichi Hashizume, Prof. Tatsuya Matsumoto In this class, aiming to understand the reactor physics, radiation measurements and shielding, safety engineering, nuclear fuel engineering, and nuclear fuel cycle comprehensively, the following experiments and practices will be performed to acquire the technology of nuclear fuel cycle: 1. isotope separation 2. chemical coprecipitation 3. heat transfer in a particle packing medium manual of experiments and practices Evaluate based upon attendance and report 43

44 Additional Specialized subjects or Cross-disciplinary Courses Targeted Code M1847 Subtitle Electricity and Magnetism for Radiation Detection Spring and Summer Credit(s) 1 teacher Prof. Naoko Iyomoto 量子線計測学や加速器科学の分野において必要とされる 電磁界 電磁波 荷電粒子と電磁界の相互作用に関する理解を深めるため 本科目では以下の項目を取り扱う 1. 静電場と静磁場 2. マクスウェル方程式 3. 電磁場のエネルギー 4. 真空中での電磁波の伝播 5. 物質中での電磁波の伝播 6. 導波管中の電磁波の伝播 7. 電磁波の放射 8. 相対論と電磁気学 講義と演習 授業中の演習 期末の演習レポート 44

45 Additional Specialized subj Targeted ects or Cross-disciplinary C ourses 2nd year Code M1848 Subtitle Science and Engineering of Organic Materials Property Spring and Summer Credit(s) 2 teacher Prof. Hirotaka Okabe Knowledge of the department level dynamics, thermodynamics, electromagnetics This class provide the knowledge about organic material application based on engineering with physical aspects including principle of the associated physical measurements, especially dielectric properties and measurements. Every material has its own dielectric property reflecting its structure. Furthermore, heterogeneous materials, industrial products and biological bodies also have their own dielectric properties reflecting their structure. Therefore, it is possible to know the internal structure of these substances by examining their dielectric property. The followings are the list of the contents. 1. Basics about polymers 2. Dielectric phenomena 3. Complex dielectric constant 4. Dielectric relaxation 5. Measurement method 6. Application examples Lecture or seminar style Lecture by original stuff Need an appointment Evaluate by the class-end examination or report. The 60% attendance is needed for the evaluation. 45

46 Additional Specialized subjects Targeted or Cross-disciplinary Courses Code M1849 Subtitle Experimental Methods fir Condenced Matter Physics I Fall Credit(s) 1 teacher Prof. Tatsuya Kawae 物理学の進展は常に実験技術の進展に支えられてきた また これらの進展が新しい実験技術を生んできた 本講義では物性実験を行う上で非常に重要な技術となっている 低温領域における物理実験法の学習を中心に授業を進める まず液体ヘリウム温度以下の低温生成法を学ぶ その後 超伝導量子干渉計 (SQUID) や超伝導マグネットなど超伝導現象を利用した物性実験法を学ぶ 最後にこれら 低温 強磁場 などの技術と 超高圧 技術を組み合わせた多重極現環境下の物性実験法について学び その具体的成果について紹介する 46

47 Additional Specialized subjects or Cross-disciplinary Courses Targeted Code M1850 Subtitle Experimental Methods fir Condenced Matter Physics II Winter Credit(s) 1 teacher Prof. Tatsuya Kawae 物理学の進展は常に実験技術の進展に支えられてきた また これらの進展が新しい実験技術を生んできた 本講義では物性実験を行う上で非常に重要な技術となっている 低温領域における物理実験法の学習を目的に授業を進める まず液体ヘリウム温度以下の低温生成法を学ぶ その後 超伝導量子干渉計 (SQUID) や超伝導マグネットなど超伝導現象を利用した物性実験法を学ぶ 最後にこれら 低温 強磁場 などの技術と 超高圧 技術を組み合わせた多重極現環境下の物性実験法について学び その具体的成果について紹介する 47

48 Additional Specialized subj Targeted ects or Cross-disciplinary C ourses Code M1851 Subtitle Medical Application of Particle Beam Fall and Winter Credit(s) 1 Intensive lecture teacher Prof. Akihiro Noutomi 量子線の医療への応用を中心にして 以下の項目について学ぶ (1) 量子線による診断と治療の基礎電磁波や粒子線等の量子と生体 検出器等の物質との相互作用を学ぶ また これらの量子線によって生体内情報が抽出され 最終的に診断画像が得られる機序を学ぶ また 量子線治療で最も重要な 最良の空間的線量分布を得るための基礎知識を学ぶ (2) 最近のトピックス量子線の医療応用に関する最近の話題について学ぶ 診断においては 各種 CT (PET MRI) における画像再構成法や放射光単色 X 線の利用を学ぶ また 最新の治療法である重粒子線 陽子線治療に関しても その原理と実際を学ぶ (3) 保健物理学量子線の生体への影響について 分子レベル 細胞レベル 組織レベルで理解し 確定的影響 確率的影響 遺伝的影響 急性効果 晩発効果等について学ぶ 資料プリント OHP スライドを用いて 講義する 資料を配付 出席点 50 % レポート点 50 % で評価する 48

49 Additional Specialized subjects or Cross-disciplinary Courses Targeted Code M1852 Subtitle Communication for Science and Engineering Presentation technics teacher Prof. Kazuya Idemitsu Prof. Yaohiro Inagaki Yoshio Hida (part-time lecturer) Spring and Summer Credit(s) 1 Intensive lecture 1. Purpose, method and evaluation of academic lecture presentation 2. Attitude at and preparation for academic lecture presentation 3. Methods of structuring lectures and preparing drafts 4. Methods of making slides and other materials 5. Method of making drafts 6. Presenting techniques 7. Particularity of presentations in English 8. Practical presentation Lecture and practical skills A guide book is distributed Evaluate based upon practical skills, etc. 49

50 Additional Specialized subjects or Cross-disciplinary Courses Targeted Code M1853 Subtitle Introduction to Applied Quantum Physics and Nuclear Engineering teacher Spring and Summer Credit(s) 2 Pending Lecture concerning applied quantum physics and nuclear Engineering for students who did not learn these fields. For students who did not learn applied quantum physics and nuclear engineering fields 50

51 Additional Specialized subjects or Cross-disciplinary Courses Targeted Code M1854 Subtitle Special Seminar in Applied Quantum Pyusics and Nuclear Engineering teacher Spring and Summer Credit(s) 1 Pending Lecture on basic knowledge concerning applied quantum physics and nuclear Engineering for students who did not learn these fields For students who did not learn applied quantum physics and nuclear engineering fields 51

52 Additional Specialized subjects Targeted 1st or Cross-disciplinary Courses year Code M1855 Subtitle Current Topics in Nuclear and Radiation Engineering I teacher Spring and Summer Credit(s) 1 Intensive lecture Pending Lecture concerning Nuclear and Radiation Engineering given by par time lecturer Intensive lecture Distribute necessary diagrams Evaluated by the attendance to class and report, maybe by examination. 52

53 Additional Specialized subjects or Cross-disciplinary Courses Targeted Code M1856 Subtitle Current Topics in Nuclear and Radiation Engineering II teacher Fall and Winter Credit(s) 1 Intensive lecture Pending Lecture concerning Nuclear and Radiation Engineering given by par time lecturer Intensive lecture Distribute necessary diagrams Evaluated by the attendance to class and report, maybe by examination. 53

54 Additional Specialized subjects or Cross-disciplinary Courses Targeted 2nd year Code M1857 Subtitle Current Topics in Nuclear and Radiation Engineering III teacher Spring and Summer Credit(s) 1 Intensive lecture Pending Lecture concerning Nuclear and Radiation Engineering given by par time lecturer Intensive lecture Distribute necessary diagrams Evaluated by the attendance to class and report, maybe by examination. 54

55 Additional Specialized subjects or Targeted Cross-disciplinary Courses 2nd year Code M1858 Subtitle Current Topics in Nuclear and Radiation Engineering IV teacher Fall and Winter Credit(s) 1 Intensive lecture Pending Lecture concerning Nuclear and Radiation Engineering given by par time lecturer Intensive lecture Distribute necessary diagrams Evaluated by the attendance to class and report, maybe by examination. 55

56 Additional Specialized subjects or Cross-disciplinary Courses Targeted Code M1859 Subtitle Current Topics in Nuclear Energy Systems I teacher Spring and Summer Credit(s) 1 Intensive lecture Pending Lecture concerning Nuclear Energy Systems given by par time lecturer Intensive lecture Distribute necessary diagrams Evaluated by the attendance to class and report, maybe by examination. 56