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課程名稱 |
奈米科技導論
Introduction to Nanotechnology |
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開課學期 |
108-1 |
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授課對象 |
工學院 分子科學與技術國際研究生博士學位學程 |
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授課教師 |
張嘉升 |
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課號 |
Phys8098 |
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課程識別碼 |
222ED5340 |
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班次 |
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學分 |
3.0 |
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全/半年 |
半年 |
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必/選修 |
選修 |
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上課時間 |
星期一6,7,8(13:20~16:20) |
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上課地點 |
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備註 |
本課程以英語授課。原分所209教室
限博士班
總人數上限:20人 |
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課程簡介影片 |
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核心能力關聯 |
核心能力與課程規劃關聯圖 |
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課程大綱
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為確保您我的權利,請尊重智慧財產權及不得非法影印
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課程概述 |
Introduction to Nanotechnology (B)
Credits: 3
Instructors: Dr. Lin,Wen-Chin 林文欽
Class hour: Monday 13:30-16:30
Classroom: Room R209, IAMS, AS
Introduction
We will go through the following topics: 1. Crystalline Structure, 2. Length Scales, Review of Linear Algebra, 3. Quantum Mechanics Review, 4. Model Quantum Mechanics Problem, 4. Density of states and Energy Bands, 6. Solid state physics: from insulator to semiconductor and super conductor, 7. Magnetism and magnetic materials, 8. Experimental Facility-Photoelectron emission: XPS, UPS and NSRRC, 9. Experimental Facility-Electron Microscopy: SEM, TEM and STM, 10. Introduction to nanomagnetism, 11. Introduction to 2-dimentional materials, 12. Other topics of nanoscience
We will adjust the pace of the course and materials covered according to the average level of the students. In general, we expect the students to put in significant effort to grasp the basics. |
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課程目標 |
Syllabus
Outline
Chap. 2 Crystalline Structure p. 9~29 (20)- 2.1 Introduction 2.2 Basic properties 2.3 Examples of crystal structures 2.4 Miller indices 2.5 Surface-to volume ratio
Chap. 3 Length Scales p. 29~61 (32)- 3.1 Introduction 3.2 de Broglie wavelength 3.3 The Bohr radius 3.4 Excitons 3.5 Confinement regimes 3.6 Metals 3.7 The Fermi energy, Fermi velocity, and Kubo gap 3.8 The mean free path in metals 3.9Charging energy
Review of Linear Algebra
Chap. 6 A Quantum Mechanics Review p. 101~137 (36)- 6.1 Introduction 6.2Wavefunctions 6.3 Observables and the correspondence principle 6.4 Eigenvalues and eigenfunctions
6.5 Wave packets 6.6 Expectation values 6.7 Dirac bra-ket notation 6.8 Operator math 6.9 More on operators
6.10 Commutators 6.11 More commutator relationships 6.12 The uncertainty principle 6.13 The Schrodinger equation
6.14 The postulates of quantum mechanics 6.15 Time-independent, nondegenerate perturbation theory
Chap. 7 Model Quantum Mechanics Problem p.137~179 (42)- 7.1 Introduction 7.2Standard model problems 7.3 Model problems for wells, wires, and dots
Chap. 8 Additional Model Problems p.179~203 (24)- 8.1 Introduction 8.2 Particle in a finite one-dimensional box 8.3 Particle in an infinite circular box 8.4 Harmonic oscillator (This chapter can be omitted if there is not enough time. It is more important that the students do some calculation.)
Chap. 9 Density of states p.203~239 (36) 9.1 Introduction 9.2 Density of states for bulk materials, wells, wires, and dots 9.3 Population of the conduction and valence bands 9.4 Quasi-Fermi levels 9.5 Joint density of states
Chap. 10 Bands p. 239~275 (36) (This chapter involves many concepts and need some supplemental material.)- 10.1 Introduction 10.2 The Kronig-Penney model 10.3Kronig-Penney model with delta-function barriers
10.4 Other band models 10.5 Metals, semiconductors, and insulators
Magnetism and magnetic materials,
Experimental Facility-Photoelectron emission: XPS, UPS and NSRRC,
Experimental Facility-Electron Microscopy: SEM, TEM and STM,
Lab. tour
Introduction to nano-magnetism, 2-dimentional materials and nano-catalyst
Other topics of nanoscience
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課程要求 |
待補 |
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預期每週課後學習時數 |
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Office Hours |
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指定閱讀 |
待補 |
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參考書目 |
Introductory NanoScience, Physical and Chemical Concepts, Masaru Kuno
Introduction to Solid State Physics, Kittel
Modern Quantum Mechanics, J. J. Sakurai
Quantum Physics of Atoms, Molecules, Solids, Nuclei, and Particles, R. Eisberg and R. Resnick |
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評量方式
(僅供參考) |
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