課程名稱 |
光電元件程式模擬 Optoelectronic Device Program Simulation |
開課學期 |
99-2 |
授課對象 |
學程 光電科技學程 |
授課教師 |
吳育任 |
課號 |
OE5060 |
課程識別碼 |
941 U0600 |
班次 |
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學分 |
3 |
全/半年 |
半年 |
必/選修 |
選修 |
上課時間 |
星期一6,7,8(13:20~16:20) |
上課地點 |
明達203 |
備註 |
總人數上限:20人 |
Ceiba 課程網頁 |
http://ceiba.ntu.edu.tw/992_opsimulation |
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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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 |
1. Introduction
2. The approach for solving of Non-linear Poisson and Drift-diffusion solver: The Gummel Iteration Method.
3. Apply this solver for studying the current-voltage behavior of pn diode LED, photo-detector, and Solar cell
4. Semiconductor crystal material and their band structure. (Numerical methods introduced: tight binding method (TBM), k.p method (k.p) and valence force field (VFF) model for strain)
5. Application of the semiconductor band structure model for analyzing
1. The influence of strain the band structure modification in the quantum well, quantum dot and SOU technology.
2. The band structure calculation of new material system such as graphene, nanowire structures.
6. Introduction of light propagation simulation: (FD-TD method for small scale problem and Monte Carlo ray tracing method for large scale problem)
7. Combination of wave simulation program with electronic simulation program in studying the light injection and extraction of Solar cell and quantum well LED.
8. Thermo-electric material: The concept of phonon, phonon propagation, the device physics of thermelectric materials and their limitation
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課程目標 |
Understand the current bottleneck of optoelectronic devices and learn how to analyze these problems by a numerical approach. We will discuss the current device problem and how to approach these topics listed in outlines listed above. |
課程要求 |
Understanding basic Semiconductor Physics:
(Solid state electronics, modern physics, nano-photonnics or semiconductor optics)
familiar with at least one computer language
(Fortran, c/c++, matlab, mathematica ...)
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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 |
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參考書目 |
教科書: Computational Electronics
Dragica Vasileska and Stephen M. Goodnick
Morgan & Claypool publishers
參考書目: Electronic and Optoelectronic Properties of Semiconductor Structures
J. Singh (Cambridge)
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評量方式 (僅供參考) |
No. |
項目 |
百分比 |
說明 |
1. |
Homework |
40% |
Homework assignment (Simulation work 40 %). Finish with all homework, you will get at least 30%. |
2. |
Final Project |
40% |
Final Project (Paper work 60%) and Oral presentation (40%) |
3. |
Participation |
10% |
Participation in the class, attendence |
4. |
Discussion |
10% |
discussion. (No discussion in class, you cannot have a chance to get A+)
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週次 |
日期 |
單元主題 |
第1週 |
2/21 |
Introduction |
第2週 |
2/28 |
Holiday. No class |
第3週 |
3/07 |
Solving the non-linear Poisson and Drift-diffusion Equation |
第4週 |
3/14 |
Continue of Drift-diffusion solver |
第5週 |
3/21 |
Introduction of 1D Poisson and Drift-diffusion Simulation program (1D-ddcc) |
第6週 |
3/28 |
Concept of Poisson Schrodinger Solver |
第7週 |
4/04 |
National Holiday |
第8週 |
4/11 |
Continue of Poisson K.p simulation. Example of Integration of band states, PL spectrum
2D-DDCC introduction, Home work discussion
(Note: Semiconductor-optics-L4 is the k.p theory told in semiconductor optics. If you have taken this class, you don't need to download it) |
第9週 |
4/18 |
Homework discussion 1D and 2D
Homework 補充材料 |
第10週 |
4/25 |
Strain calculation and band structure calculation of crystal |
第11週 |
5/02 |
Tight binding method for Full Band calculation |
第12週 |
5/09 |
Continue of tight binding method |
第13週 |
5/16 |
Maxwell Equation, FD-TD method for EM simulation |
第14週 |
5/23 |
No Class |
第15週 |
5/30 |
Dicussion Class for Homework 2 <br>
New mesh function in 2D-DDCC program |
第16週 |
6/06 |
端午節
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第17週 |
6/13 |
Simulation for carrier dynamics |
第18週 |
06/26 or 6/29 |
Final Project Report (補課時間) |
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