研究生: |
江雅涵 YA-HAN CHIANG |
---|---|
論文名稱: |
錳摻雜Cu-In-S量子點之合成及量子點敏化太陽能電池應用 Aqueous synthesis of Mn-doped Cu-In-S quantum dots and its application in quantum dots-sensitized solar cell |
指導教授: |
蔡伸隆
Shen-Long Tsai |
口試委員: |
張家耀
Jia-Yaw Chang 周宗翰 Chou, Tzung-Han |
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: | 2016 |
畢業學年度: | 104 |
語文別: | 中文 |
論文頁數: | 76 |
中文關鍵詞: | 量子點 、太陽能電池 、錳摻雜 |
外文關鍵詞: | Quantum Dot, solar cell, Mn-doped |
相關次數: | 點閱:450 下載:0 |
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本研究於水相中藉由微波輔助法,可瞬時升溫至反應溫度,在定溫均勻受熱環境下,將短鏈雙功能分子與離子前驅液置於反應瓶中快速合成,能以一步合成量子點,不需再經配位體置換之表面改質,製程簡易且快速。
量子點部分選擇不含重金屬離子之銅、銦及硫離子前驅物,合成先以改變金屬銅銦離子比例,合成出CuInS2/In2S3量子點,再進一步以共成長摻雜法摻雜錳於量子點,並將量子點進行材料分析。
量子點太陽能電池應用部分,將預合成量子點經純化配製成共吸附劑,使量子點沉積於TiO2光電極後,以連續離子吸附反應沉積ZnS鈍化層,搭配Cu2S背電極組裝成電池元件。其中,不同銅銦比例所合成出的CuInS2/In2S3量子點太陽能電池效率可達7.5 %。而錳摻雜於CuInS2/In2S3量子點後,其光電轉換效率更高達8.0 %。隨後將電池元件進行電化學分析,探討內部電子傳遞機制,以及介面阻抗對電子傳遞之影響。
In this study, we demonstrated the synthesis of colloidal quantum dot (QDs) by microwave-assisted method in aqueous phase. The advantage of using microwave-assisted method is to heat the reaction temperature instantaneously and uniformly at constant temperature. The quantum dots were synthesized by the rapid reaction of ions precursor solution and short-chain bifunctional molecules. The synthesis process is simple and fast without further surface modification of ligand exchange.
For the use of quantum dots, we selected free heavy metal ion precursors such as copper, indium and sulfur ion. The different ratio of copper and indium were first synthesized as CuInS2 and In2S3 quantum dots. By further utilize the common growth doping method, the Mn metals are doped into the previous QDs.
The application of quantum dot-sensitized solar cells (QDSSCs), pre-synthesis QDs mixed with co-adsorbent after purification. When QDs deposited on the TiO2photoelectrode,ZnS deposited as passivation layer by successive ionic layer adsorption and reaction (SILAR). Counter electrode made from Cu2S components assemblely with photoelectrode to become the cell component. Wherein the different proportions of copper indium QDs synthesis cell component efficiency up to 7.5%, Mn-doped QDs its photoelectric conversion efficiency as high as 8.0%, and the electrochemical analysis to explore the internal QDSSCs of the electron transfer mechanism and the effect of electron transfer interface impedance of the effects on electronic transfer.
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