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研究生: 鄭傑銘
Zheng,Jie Ming
論文名稱: 一階濺鍍製程製作銅銦鎵硒太陽能電池 在可撓式不銹鋼基板上
Fabrication of Cu(In,Ga)Se2 solar cells on the flexible stainless steel substrate by one-step sputtering process
指導教授: 甘炯耀
Gan,Jon Yiew
口試委員: 賴志煌
Lai,Chih Huang
謝東坡
Hsieh,Tung-Po
學位類別: 碩士
Master
系所名稱: 工學院 - 材料科學工程學系
Materials Science and Engineering
論文出版年: 2016
畢業學年度: 104
語文別: 中文
論文頁數: 74
中文關鍵詞: 銅銦鎵硒太陽能電池可撓式基板不銹鋼四元靶一階濺鍍製程
外文關鍵詞: Cu(In,Ga)Se2 solar cells, flexible substrate, stainless steel, quaternary target, one-step sputtering process
相關次數: 點閱:3下載:0
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    • 銅銦鎵硒CuIn1-XGaXSe2薄膜太陽能電池被認為是未來在太陽能產業上最具有潛力的材料之一,將CIGS薄膜太陽能電池鍍在可撓式基板開創了太陽能電池新的應用。本研究在軟性不銹鋼基板上藉由四元靶與鎵硒靶的共濺鍍開發一階濺鍍製程而不用任何額外的硒供應。在將來可搭配大面積的Roll-to-roll製程將能夠大幅的降低製程成本。

    為了在可撓式不銹鋼基板上達到高效率的太陽能電池,需要鍍製擴散阻擋層去抑制來鐵元素從基板擴散至CIGS吸收層內,鐵元素若擴散至CIGS吸收層裡面,將會在CIGS吸收層內產生深層的缺陷並對效率造成影響。我們鍍製1um的鉻當擴散阻擋層,阻擋了來自不銹鋼基板的鐵元素並改善了不銹鋼基板的粗糙度。接著在鍍製CIGS吸收層之前,為了解決不銹鋼基板沒有來自基板的鈉來源,我們濺鍍氟化納靶材提供鈉來源。CIGS的薄膜製作是以一階段共濺鍍四元靶和鎵硒二元靶的方式而成,利用共濺鍍鎵硒二元靶可以在製程中創造出鎵的正向梯度,將幫助載子的收集。我們將探討鈉元素含量對於CIGS薄膜的電性、鎵的梯度、結構特性、元件表現上的影響。

    在製程溫度600℃下,得到最好的元件轉換效率為9.15%。然而過高的工作溫度將會導致薄膜內的硒元素不足,因此限制了元件表現.從PL分析發現藉由在後退火中濺鍍硒靶補充硒元素,可有效的消除硒不足造成的缺陷以及提升薄膜品質,藉由調控適合的製程溫度以減少硒損失,在製程溫度550℃下元件轉換效率可從9.15%提升至11.25%,無須額外的硒供給。

    uIn1-XGaXSe2 (CIGS) thin-film solar cell is considered to be one of the most promising material in the future of the solar industry due to its high performance and low-cost commercial production. The CIGS thin film solar cells deposited on the flexible substrate to offer a new type of solar cell applications. In this study, we developed a one-step sputtering process by co-sputtering quaternary target and Ga2Se3 binary target without extra selenium supply on the stainless steel flexible substrate. This kind of process will be scaled up by roll-to-roll deposition process to reduce the production cost significantly.

    To reach highly efficient solar cells on the stainless steel flexible substrate,deposition of diffusion barrier is needed to suppress iron diffusion form substrate into CIGS absorber layer . If iron diffuses into the CIGS absorber layer, it will create a deep-defect in the CIGS absorber layer and detriment to efficiency. We deposited 1um Chromium (Cr) acts as a diffusion barrier to block iron from stainless steel substrate and improve the roughness of stainless steel substrate. In order to solve stainless steel substrate without extra sodium form substrate, we sputter sodium fluoride target to supply sodium source before depositing CIGS absorber layer.
    The fabrication of CIGS thin film is made by co-sputtering quaternary target and Ga2Se3 binary target in one-step sputtering process. Usage of Ga2Se3 binary target will create normal Ga-grading profile during the deposition which help carriers be collected. We will discuss the impact of sodium content of the CIGS thin film for the electrical property, Ga-grading profile, structural characteristics and device performance.

    The conversion efficiency can achieve 9.15% at 600℃.However, higher working temperature will make Se element loss in the CIGS thin films, which limit the device performance. From PL analysis, with Se supply in annealing process can remove Se-like defect transition and enhance film quality. By adjusting the temperature to reduce selenium deficiency, the conversion efficiency can be improved from 9.15% to 11.25% at 550℃without extra Se supply.

    目錄 摘要 i Abstract ii 目錄 iv 圖目錄 vi 表目錄 viii 第一章 引言 1 第二章 文獻回顧 2 2.1太陽能電池原理 2 2.1.1太陽能電池簡介 2 2.1.2電壓電流特性 4 2.2銅銦鎵硒太陽能電池 6 2.2.1 CuInxGa1-XSe2薄膜性質 6 2.2.2 CuInxGa1-XSe2太陽能電池的結構與製程 10 2.2.3 CuInxGa1-XSe2可撓式太陽能電池的簡介 15 2.2.4 CuInxGa1-XSe2薄膜內的本質摻雜和缺陷 19 2.2.5 CuInxGa1-XSe2太陽能電池的載子復合機制 22 2.2.6鈉效應 25 第三章 實驗方法與分析儀器 26 3.1 實驗流程 26 3.2 實驗設備介紹 29 3.2.1 Solar和Apollo no.1 濺鍍系統 29 3.2.2 X光繞射儀 30 3.2.3冷場發電子顯微鏡 31 3.2.4太陽光模擬器 32 3.2.5外部量子效率量測儀 33 3.2.6飛行時間二次離子質譜儀 34 3.2.7光致螢光光譜 35 第四章 結果與討論 36 4.1 不銹鋼基板性質探討 37 4.1.1雜質控制 37 4.1.2不銹鋼粗糙度 41 4.1.3小結:以鉻靶材鍍製擴散阻擋層 43 4.2鈉效應 45 4.2.1鈉來源 45 4.2.2鈉含量對於CIGS膜層性質的影響 47 4.2.3小結:濺鍍氟化鈉對於CIGS薄膜性質影響 57 4.3成分控制對薄膜性質的影響 60 4.3.1 以濺鍍硒補償硒不足對膜層的影響 61 4.3.2製程溫度對薄膜性質的影響 64 4.3.3小結:成分控制及溫度對於膜層影響 68 第五章 結論 70 參考文獻 71 圖目錄 圖2-1 P-N接面二極體的結構示意圖 2 圖2-2標準太陽能電池電壓電流特性 4 圖2-3 太陽能電池電路模型 5 圖2-4為CIGS沿Cu2Se-In2Se3二元相圖 6 圖2-5 ZnS (zinc blende structure) 和 CIGS(chalcopyrite structure) 6 圖2-6 常見太陽能電池材料吸收係數 7 圖2-7為常見的三種CIGS的能帶圖 8 圖2-8為常見CIGS太陽能電池的膜層結構 10 圖2-9 CIGS三階段共蒸鍍法 11 圖2-10 硒化製程常見的前驅層結構 12 圖2-11 化學水域法示意圖 13 圖2-12 常見可撓式基板材料和性質 15 圖2-13 不同可撓式基板效率的演變 17 圖2-14 CIS本質缺陷的電性種類與生成能量 19 圖2-15 理論計算得到的缺陷 20 圖2-16 Shockley-Read-Hall(SRH) 機制 22 圖2-17 CIGS中常見載子復合路徑 23 圖2-18 CIGS/CdS 能帶連接圖 23 圖3-1 實驗流程圖與膜層設計 26 圖3-2 X光繞射儀基本原理 30 圖3-3 電子顯微鏡原理 31 圖3-4 Hitachi S4000 冷場發式電子顯微鏡 31 圖3-5 CIGS各波段EQE表現 33 圖3-6 電子電洞對復合路徑 35 圖4-1 不同工作氣壓鍍製鉻(Cr)在玻璃基板上的表面形貌。(a)3mTorr (b)5 mTorr (c)7 mTorr (d)15 mTorr 38 圖4-2 XPS 檢測鐵元素 (左)SS/Mo 39 (右)SS/Cr/Mo 39 圖4-3基板溫度600℃,SIMS profile 檢測雜質元素 40 圖4-4 Optical microscope 500X下的不銹鋼表面 41 圖4-5 (A)為2D-AFM下的不銹鋼表面、(B)為3D-AFM下的不銹鋼表面 42 圖4-6 (A)為2D-AFM下的不銹鋼鍍完Cr表面 42 (B)為3D-AFM下的不銹鋼鍍完Cr表面 42 圖4-7 XRF訊號強度與Crystal Monitor的厚度值的檢量線 46 圖4-8基板溫度600℃,三種分別為不同的鈉含量的SEM圖 由鈉的含量少到多依序為NaF 0,NaF 40nm,NaF 80nm 48 圖4-9 XRD結構分析,基板溫度600℃,比較NaF 80nm與沒有鈉的條件對於CIGS結構的變化 49 圖4-10基板溫度600℃,SIMS-without NaF,with NaF80nm 各元素的縱深分布 51 圖4-11 比較沒有添加鈉與NaF 80nm下GGI的縱深分布情形 52 圖4-12 SIMS-鈉在CIGS裡分布的情形 52 圖4-13基板溫度600℃, NaF 0nm,40nm,80nm,140nm鍍製的CIGS其光伏參數 54 圖4-14基板溫度600℃, NaF 0nm,40nm,80nm,140nm鍍製的CIGS其C-V 分析結果 55 圖4-15 基板溫度600℃, NaF 80nm,NaF 140nm鍍製的CIGS其元件的QE分析結果 57 圖4-16基板溫度600℃下鍍製CIGS,最佳元件表現的I-V曲線 58 圖4-17 基板溫度600℃, NaF 100nm 鍍製的CIGS其元件的QE分析 59 圖4-18 基板溫度600℃, NaF 100nm 鍍製的CIGS其元件的能係大小分析 60 圖4-19 吸收層的鍍製過程示意圖 61 圖4-20 PL分析基板溫度600℃,比較有無濺鍍硒鍍製CIGS特徵峰 63 圖4-21 分別是基板溫度520℃、550℃、580℃、600℃,不同溫度下鍍製的CIGS薄膜表面形貌 66 圖4-22基板溫度550℃下鍍製CIGS,最佳元件表現的I-V曲線 69 表目錄 表4-1 ICP-MASS 檢測結果-不銹鋼箔片成分組成 37 表4-2不同基板粗糙度的比較 43 表4-3 基板溫度600℃, NaF 0nm,40nm,80nm,140nm鍍製的CIGS其空乏區長度與載子濃度的改變 56 表4-4 XRF分析基板溫度600℃, NaF 100nm 鍍製的CIGS的成分 61 表4-5 XRF分析基板溫度600℃,比較有無濺鍍硒鍍製CIGS的成分 62 表4-6 PL分析基板溫度600℃,比較有無濺鍍硒鍍製CIGS特徵峰位置說明 63 表4-7基板溫度600℃,比較有無濺鍍硒鍍製CIGS元件的參數平均 64 表4-8 XRF分析基板溫度600℃、580℃、550℃、520℃,鍍製CIGS的成分 65 表4-9基板溫度600℃、580℃、550℃、520℃鍍製CIGS元件的參數平均 67

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