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課程名稱 |
光電高分子科技專論
Special Topics in Electro-optic Polymers |
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開課學期 |
100-2 |
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授課對象 |
學程 光電科技學程 |
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授課教師 |
鄭如忠 |
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課號 |
PSE7017 |
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課程識別碼 |
549 M4010 |
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班次 |
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學分 |
3 |
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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 |
星期五2,3,4(9:10~12:10) |
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上課地點 |
共309 |
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備註 |
總人數上限:48人 |
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Ceiba 課程網頁 |
http://ceiba.ntu.edu.tw/1002PSE7017 |
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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 |
This course comprises the following chapters:
Chap. 1. Introduction
Chap. 2. Nonlinear Optics
Chap. 3. Liquid Crystals
Chap. 4. OLEDs and PLEDs
Chap. 5. Polymer Solar Cells
Chap. 6. Other Relevant Fields |
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課程目標 |
Opto-electronic polymers have become omnipresent in our daily lives. Particularly, the flat panel display and advanced energy generation technologies, have made remarkable gains in recent years. This course attempts to expound the field in a manner that the students will be able to understand, such as why a given product operates in a certain way and what are the reasons for using polymeric materials to fabricate opto-electronic devices. |
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課程要求 |
Prior experiences with Polymer Chemisry and Physics |
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預期每週課後學習時數 |
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Office Hours |
備註: Tue.: 2-3 p.m.
Thur.: 2-3 p.m. |
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指定閱讀 |
Lecture notes will be provided. |
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參考書目 |
1. "Polymers for Second-Order Nonlinear Optics", edited by G. A. Lindsay and K. D. Singer, ACS, Washighton, DC 1995.
2. C. C. Chang, et al. “Polymers for Electro-Optical Modulation”, J. Macro. Sci., Polym. Reviews, 45 (2005) 125-170.
3. Y. J. Cheng et al. "Synthesis of Conjugated Polymers for Organic Solar Cell Applications", Chem. Rev., 2009, 109 (11), pp 5868–5923
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評量方式
(僅供參考) |
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週次 |
日期 |
單元主題 |
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第1週 |
2/24 |
syllabus and brief introduction of optoelectronic polymers. |
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第2週 |
3/02 |
Chap. 1. Introduction of opto-electronics
Chap. 2. Nonlinear Optics-Pockels effect, EO modulator |
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第3週 |
3/09 |
Continue on Chap.2. Nonlinear Optics: guest-host system, side-chain system, main-chain system, and crosslinked system; in situ poling, order parameter, cut-off wavelength, resonance enhancement, first hyperpolarizability, thermal degradation of chromophores, high Tg Polyimide. |
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第4週 |
3/16 |
Continue on Chap. 2 Nonlinear Optics: side-chain system, main-chain sytstem, and crosslinked system: photocrosslinked system--the fatal issue: photodegradation of NLO chromophore; thermal fluctuation leads to poor poling efficiency; a detrimental point of thermally crosslinked system: ununiform crosslinking density; sol-gel materials with poor waveguide properties: heteregeneous components (organic/inorganic); pop quiz 1: what is order parameter? |
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第5週 |
3/23 |
Continue on Chap. 2 Nonlinear Optics: crosslinked systmem: lattice hardening system; the difference between hybrid ande composite; organic sol-gel materials; all sol-gel organic/inorganic materials, dendrimer system, and self-assembly system, lattice-hardening system; pop quiz 2: pros and cons of side-chain and main-chain system. |
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第6週 |
3/30 |
lambda-shaped chromohores, their guest-host system, and main-chain PU system; pop quiz 3: pros and cons of NLO crosslinked system |
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第7週 |
4/06 |
spring break |
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第8週 |
4/13 |
Thermally stable NLO materials via sol-gel process: sol-gel reaction, organic-inorganic system, polyimide/inorganic system, all organic sol-gel system, nanocomposite system, semi-IPN system, full IPN system, and hybrid system; pop quiz: the choice of fundmental wavelength when taking UV-vis absorption behavior into account.
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第9週 |
4/20 |
mid-term |
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第10週 |
4/27 |
Orderly arranged NLO materials based on chromophore-containing dendrons on exfoliated layered templates.
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第11週 |
5/04 |
Synthesis of Dendrons with Two Alternating Peripheral Functional Groups
and Their Applications in Electro-Optics;Thermally Stable NLO Polymers via Sequential Self-Repetitive Reaction(SSRR)
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第12週 |
5/11 |
leave of absence |
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第13週 |
5/18 |
continue on Thermally Stable NLO Polymers via Sequential Self-Repetitive Reaction(SSRR); NLO Papers Illustrated As Individual Examples for Research |
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第14週 |
5/25 |
Introduction to OLEDs: theory of photoluminescence and electroluminescence; stoke shift and anti-stoke shift; HOMO, LUMO and energy gap. |
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第15週 |
6/01 |
eternal quantum yield and internal quantum yield; hole and electron transport; charge mobility, time of flight methold; energy transfer: Förster Energy Transfer, Dexter Engergy Transfer, guest emitter, host emitter. |
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第16週 |
6/08 |
CIEx,y 1931; degree of colorfulness; color gamut; Luminance Efficiency (cd/A); Power Efficiency (lm/W); I-V-L characteristics of the OEL device.
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第17週 |
6/15 |
Charge Injection and Transporting Materials: configuration of OLEDs, hole transport layer (materials), electron transport layer (materials), emitting layer (materials).
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