課程名稱 |
半導體光學 SEMICONDUCTOR OPTICS |
開課學期 |
99-1 |
授課對象 |
學程 奈米科技學程 |
授課教師 |
吳育任 |
課號 |
OE5004 |
課程識別碼 |
941 U0090 |
班次 |
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學分 |
3 |
全/半年 |
半年 |
必/選修 |
選修 |
上課時間 |
星期三6,7,8(13:20~16:20) |
上課地點 |
電二104 |
備註 |
研究所一般課程。 總人數上限:24人 |
Ceiba 課程網頁 |
http://ceiba.ntu.edu.tw/991_semioptics |
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 |
課程大綱
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課程概述 |
1. Structure properties of Semiconductor: Crystal growth, crystal structures,
Strain in heterostructure, polar materials, semiconductor Electronic equations,
Semiconductor p-n diodes.
2. Reviews on quantum mechanic theory: Schrodinger equations, square quantum
well, time-independent/time independent perturbation theory.
3. Semiconductor band structure: Block theorem of crystal, tight binding method,
spin orbit coupling, K.P method.
4. Band structure modification: Band structure of alloys, Band structure in
quantum well and quantum dot, strain and deformation potential theory, polar
heterostructures.
5. Transport and Scattering theory: Defect and carrier-carrier scattering
(ionized impurity scattering, charged dislocation scattering, alloy scattering
and interface roughness scattering) Lattice vibrations, phonon scattering
(acoustic phonon scattering and optical phonon scattering, deformation potential
scattering.
6. Optical properties of semiconductors: Maxwell’s equations and vector
potential, interband transitions, indirect interband transitions, charge
injection, radiative recombination, non-radiative recombination, and LEDs.
7. Excitonic effects: Excitonic states in semiconductors, optical properties
with inclusion of excitonic effects, excitonic states in quantum well, excitonic
absorption, and excitonic broadening.
8. Modulations of optical properties: Modulation of optical properties,
Electro-optic effect, and quantum confined stark effect.
9. Selected Topics of Current Research: Optical properties of intrinsic excitons in reduced dimension, Exciton under external fields - electric, strain, and magnetic fields.Prepare students with knowledge and skills to understand and analyze the milestone papers in the area of semiconductor optics, extend the learned knowledge to analyze the linear optical process occurred in low dimensional quantum confined structures |
課程目標 |
Student in this course will learn how to Calculating the bandstructure of semiconductor device, carrier transport mechanism, carrier-photon absorption and recombination calculation, etc.. |
課程要求 |
評分: 作業: 30% 期中考: 30% 期末考: 40% |
預期每週課後學習時數 |
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Office Hours |
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指定閱讀 |
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參考書目 |
教科書
Jasprit Singh, "Electronic and Optoelectronic Properties of Semiconductor Structures", Cambridge ISBN 0-521-82379-X 新月書局代理
參考書目
(1) C.F. Klingshirn, “Semiconductor Optics,” Springer-Verlag (1995, ISBN 3-540-58312-2) (歐亞書局經銷)
(2) E.L. Ivchenko and G. E. Pikus, “Superlattices and Heterostructures:
symmetry and optical phenomena”, Springer Verlag (1995, 臺大工圖 QC611.6.06 I89) |
評量方式 (僅供參考) |
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週次 |
日期 |
單元主題 |
第1週 |
9/15 |
Introduction, Crystal, Strain |
第2週 |
9/22 |
休假 無課 |
第3週 |
9/29 |
Concepts of heterostructure. Review of quantum mechanics, density of state theory, quantum well , quantum dot |
第4週 |
10/06 |
Bloch theorem, tight binding method |
第5週 |
10/13 |
Tight Binding method, Spin orbital coupling |
第6週 |
10/20 |
Spin orbital coupling, K.p method |
第7週 |
10/27 |
Semiconductor band structures, doping, and alloys |
第8週 |
11/03 |
Semiconductor band structures, doping, and alloys |
第9週 |
11/10 |
Modification of bandstructures: strain, and deformation theory |
第10週 |
11/17 |
Continue of deformation potential theory.
Computer homework
Introduction of Boltzmann transport theory |
第11週 |
11/24 |
Midterm
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第12週 |
12/01 |
Carrier Transport Issue and Monte Carlo method
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第13週 |
12/08 |
Maxwell equations and Vector Potential Interband transitions: Bulk and 2D and quantum well
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第14週 |
12/15 |
Interband transition in quantum well
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第15週 |
12/22 |
indirect transition, carrier injection, Nonradiative process, LEDs and Laser |
第16週 |
12/29 |
indirect transition, carrier injection, Nonradiative process, LEDs and Laser |
第17週 |
1/05 |
Excitonic effects in 3D and lower dimensions Excition and electro-optic effect |
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