開課內容 |
上學期
課程名稱 |
(中文)化合物半導體 |
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(英文) Compound Semiconductors |
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開課單位 |
電機系 |
授課教師 |
綦振瀛 |
課程代碼 |
EE7039 |
選課性質 |
選修 |
學分數 |
3 |
開課年級 |
四年級 研究所 |
課程概述 |
本課教授內容包括常見化合物半導體之晶體成長及磊晶技術、能帶特性、載子傳輸特性以及光學特性,並以各種異質結構所形成之元件為例,介紹化合物半導體元件之工作原理及應用場合。 |
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課程目標 |
修習者能了解化合物半導體材料之製備技術,特有之光電特性,掌握現有化合物半導體元件之工作原理,並據此可以發展元件結構設計之能力。 |
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教科書 |
Electronic and Optoelectronic Properties of Semiconductor Structures by Jasprit Singh |
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參考書 |
Materials Aspects of GaAs and InP Bases Structure by V.Swaminathan and A.T. Macrander |
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評量方式 |
期中考、期末考、報告 |
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單元主題 |
單元綱要 |
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Introduction |
- What are the typical compound semiconductors - Applications |
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Material Preparation |
- Bulk growth - Epitaxy - LPE - VPE - MOCVD - MBE |
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Semiconductor physics & Properties |
- Electronic properties - Crystal structure and bandgap - Density of states and effective mass - Alloys and heterostructures - Strain - Transport properties - Mobility and Scattering mechanisms - Optical properties - Fermi golden rule - Interband transitions - Intraband transitions - Excitons in low-dimensional structures - Nonradiative processes |
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Device Applications |
- Optical devices - LED - LD + VCSEL - PD - Modulator - Electronic devices - MESFET - HEMT - HBT - RTD |
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下學期
課程名稱 |
(中文)近代物理 |
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(英文) Modern Physics |
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開課單位 |
電機系 |
授課教師 |
綦振瀛 |
課程代碼 |
EE2023 |
選課性質 |
選修 |
學分數 |
3 |
開課年級 |
二 |
課程概述 |
本課以歷史上著名之各種實驗與發現介紹物質與光均具有波性及粒子性,隨而引出微觀世界量子化的概念。結合所闡述的量子物理及統計物理,吾人可以了解原子、分子及固體之光譜成因以及其物理化學特性。本課程也將介紹基本的半導體物理及其元件工作原理。 |
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課程目標 |
學習者能夠具有基本的量子物理及統計物理觀念,了解半導體之能帶理論及其基本特性,為學習半導體元件、光電元件、奈米元件奠定基礎。 |
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教科書 |
Modern Physics, 3rd Ed. by Serway, Moses and Moyer |
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參考書 |
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評量方式 |
期中考、期末考 |
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單元主題 |
單元綱要 |
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The quantum theory of light |
Blackbody radiation Planck’s law Photoelectric effect Compton effect and x-rays Particle-wave complementarity |
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The particle nature of matter |
The composition of atoms The Bohr atom The Franck-Hertz experiment |
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Matter waves |
De Broglie wavelength The Dvisson-Germer experiment Matter wave packets The Heisenberg uncertainty principle The wave-particle duality |
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Quantum mechanics in one dimension |
The Born interpretation Particle in a box The finite square well The quantum oscillator Expectation values Tunneling phenomena |
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Quantum mechanics in three dimensions |
Particle in a three-dimensional box Space quantization Quantization of angular momentum and energy Atomic Hydrogen |
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Atmoic structure |
Zeeman effect The spinning electron The spin-orbit interaction The exclusion principle The periodic table X-ray spectra and Moseley’s law |
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Statistical Physics |
The Maxwell-Boltzmann distribution Bose-Einstein distribution Fermi-Dirac distribution |
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Molecular structure |
Bonding mechanisms Molecular rotation and vibration Molecular spectra |
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The solid state |
Bonding in solids Quantum theory of metals Band theory of solids Semiconductor devices Superconductivity Lasers |
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