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研究生: 吳斌龍
Bin-Long Wu
論文名稱: I-II-III-VI族量子點敏化太陽能電池合成與鑑定
Synthesis of I-II-III-VI Group Quantum dots-Sensitized Solar Cell
指導教授: 張家耀
Jia-Yaw Chang
口試委員: 曾堯宣
Yao-Hsuan Tseng
曾新華
none
學位類別: 碩士
Master
系所名稱: 工程學院 - 化學工程系
Department of Chemical Engineering
論文出版年: 2014
畢業學年度: 102
語文別: 中文
論文頁數: 90
中文關鍵詞: 量子點敏化太陽能電池連續離子層吸附反應法
外文關鍵詞: QDSSC, SILAR
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    • 本研究採用預先合成法(Pre-synthesis)合成出Zn-CuInS2 (Z-CIS)與Cd-CuInS2 (Cd-CIS)四元量子點,透過改變前驅物比例,探討量子點材料特性與光電性質。利用其量子點作為量子點敏化太陽能電池(QDSSC)的光敏化劑,並使用寬能隙ZnS作為鈍化層,防止量子點及TiO2直接接觸到電解液造成暗電流產生。最後光電極與高比表面積之Cu2S背電極結合形成三明治結構之電池元件,在Cd-CIS QDSSC可獲得1.70%的光電轉換效率。為了更進一步提升效率,我們結合連續離子層吸附反應法(Successive Ionic Layer Adsorption and Reaction, SILAR)沉積CdS與CdSe量子點於光電極上,比較Cd-CIS/CdS(3)與Cd-CIS/CdSe(4)兩電極,發現後者有較佳的光電轉換效率,主要是因為CdSe有較寬的吸收範圍透過IPCE的測量,其起始吸光波長為670 nm,IPCE值在485 nm處有最大值為65%。最適化的電池結構為Cd-CIS/CdSe(4)/ZnS(3)||Cu2S,其電流密度Jsc為9.73 mA cm-2;開路電壓Voc為0.555 V;填充因子FF為53.0%,整體光電轉換效率高達2.86%。

    In this study, we demonstrated synthesis of Zn-CuInS2 (Z-CIS) and Cd-CuInS2 (Cd-CIS) quantum dots (QDs) through pre-synthesis method. Motivated on providing QDs as excellent sensitizer for quantum dot-sensitized solar cells (QDSSC), the effect of precursor on the optical and electrical properties of quantum dots was regularly investigated. In the synthesis process, the zinc sulfide (ZnS) was further deposited on a photo-electrode as a passivation layer to prevent the current leakage on QDs, while electrolyte and counter electrode (Cu2S) are used to form sandwich structure of QDSSC. The power conversion efficiency (PCE) of Cd-CIS-based QDSSC was 1.70%. To improve the efficiency value, we subsequently combined CdS or CdSe as the co-sensitization. The photocurrent response from incident light was evaluated by Incident Photon to Current Conversion Efficiency (IPCE), with photocurrent onsets at 640 nm for the Cd-CIS/CdS and 670 nm for Cd-CIS/CdSe-based solar cells. The best device was performed by the Cd-CIS/CdSe(4)/ZnS(3) configuration where showed Jsc, Voc, FF, and values up to 9.73 mA cm-2, 0.555 V, 53.0%, and 2.86%, respectively.

    摘要 i Abstract ii 總目錄 iii 表目錄 v 圖目錄 vi 第一章、序論 1 1.1 前言 1 1.2 研究動機與內容 2 第二章、理論背景與文獻回顧 3 2.1 奈米材料─基本性質 3 2.2.1表面效應 3 2.2.2小尺寸效應 4 2.2.3 量子尺寸效應 5 2.2 染料敏化太陽能電池 6 2.2.1 起源與發展 6 2.2.2工作原理 7 2.2.3元件介紹 9 2.3 量子點應用於敏化太陽能電池 13 2.3.1 量子點特性 14 2.3.2 量子點敏化太陽能電池發展 17 2.3.3 量子點製備 20 2.3.4分離與純化 26 第三章、實驗 30 3.1 實驗架構 30 3.2 實驗藥品 31 3.3實驗步驟 34 3.3.1 導電玻璃基板清洗 34 3.3.2 二氧化鈦光電極薄膜製備 34 3.3.3 量子點合成 35 3.3.4 量子點吸附 36 3.3.5 共敏化劑沉積 37 3.3.6 鈍化層沉積 38 3.3.7 背電極製作 39 3.3.8 電解液配置 39 3.3.9dQDSSC元件組裝 39 3.4 實驗儀器與設備 41 3.5 樣品分析 43 第四章、結果與討論 50 4.1 量子點材料分析 50 4.1.1 CuInS2量子點分析 50 4.1.2 Zn-CuInS2與Cd-CuInS2量子點分析 53 4.2 –QDSSC組件分析 63 4.3 –QDSSC效率分析 65 4.3.1 量子點前驅物比例對電池元件之影響 65 4.3.2 共敏化效應對電池元件之影響 68 第五章、結論 73 參考文獻 74

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