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研究生: 葉雲友
Yun-Yu Yeh
論文名稱: 以射頻磁控濺鍍法製備二氧化鈦光觸媒玻璃之製程參數與特性研究
Process Parameters and Thin Film Properties for Titania Photocatalytic Glass by RF magnetron sputtering
指導教授: 鄧敦平
Teng, Tun-Ping
學位類別: 碩士
Master
系所名稱: 工業教育學系
Department of Industrial Education
論文出版年: 2011
畢業學年度: 99
語文別: 中文
論文頁數: 114
中文關鍵詞: 射頻磁控濺鍍法二氧化鈦薄膜光催化特性
英文關鍵詞: RF magnetron sputtering, TiO2 thin films, photocatalytic properties
論文種類: 學術論文
相關次數: 點閱:169下載:16
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  • 本研究以射頻磁控濺鍍法(RF magnetron sputtering),使用高純度金屬鈦為
    靶材,利用一階氧化製程且不另外加熱方式將二氧化鈦(Titania, TiO2)薄膜直
    接沉積於玻璃基材上,成功製作出TiO2 光觸媒玻璃。藉由氣氛比例、氣體流量
    與沉積時間之參數改變,探討實驗參數對TiO2 薄膜結構與特性的影響。利用XRD、
    HR-FESEM、AFM 等儀器進行量測並分析製程參數 與薄膜特性關係,篩選出較
    佳的鍍膜參數,作為後續光催化特性實驗的樣本。接著利用光譜儀配合亞甲基藍
    污染物與接觸角量測儀進行鍍膜玻璃之光學、親疏水與光催化降解污染物的特性
    量測,相關特性實驗結果配合第一次篩選出的鍍膜參數,即可決定最佳鍍膜參數,
    提供後續鍍膜玻璃對於太陽能電池輸出性能影響之研究使用。實驗結果顯示,鍍
    膜玻璃在紫/紅外線波段的穿透值有明顯下降,顯示鍍膜具有抗紫/紅外線的性能。
    在水滴接觸角量測方面,證明製備的二氧化鈦薄膜具光致超親水特性,接觸角最
    佳可達3.58 度。在光催化降解亞甲基藍實驗方面,最佳樣本的亞甲基藍降解率
    可提昇至對照組的4 倍。最後在鍍膜玻璃對於太陽能電池輸出性能影響方面,鍍
    膜玻璃可降低太陽能電池表面溫度與提升太陽能電池的輸出性能。未來將利用此
    最佳薄膜製程參數,能夠應用於製造小範圍且具極高實用性的相關產品。

    In this study, radio frequency (RF) magnetron sputtering is used for the
    successful production of thin films of titania (TiO2) on glass substrates using a highly
    pure Ti target without additional external heating in a one-stage oxidation process.
    The effects of the O2 and Ar flow ratio, gas flow, and deposition time on the structure
    and characteristics of TiO2 thin films are studied, and the relationship between these
    parameters and the film properties are investigated by X-Ray Diffraction (XRD),
    High Resolution Field Emission Scanning Electron Microscope (HR-FESEM),
    Atomic Force Microscope (AFM), and other equipment. The optimal coating
    parameters are selected a photocatalytic properties experiments. In addition, the
    degradation of the methylene blue aqueous solution and the water contact angle are
    used to evaluate the optical characteristics, and the hydrophilic, hydrophobic, and
    photocatalytic degradation of pollutants for TiO2 thin films. The first screening of the
    coating parameters can determine the optimal process parameters for TiO2 coated
    glass in solar cell output performance experiments.

    摘 要 i ABSTRACT ii 誌 謝 iv 目 錄 v 表目錄 vii 圖目錄 viii 第壹章 緒論 1 1.1前言 1 1.2研究動機 2 1.3研究目的 3 1.4研究方法 3 1.5論文架構 5 1.6文獻回顧 6 1.6.1.氬氧比例對二氧化鈦薄膜性質之影響 6 1.6.2.射頻功率對二氧化鈦薄膜性質之影響 7 1.6.3.基板溫度對二氧化鈦薄膜性質之影響 8 1.6.4.製程壓力對二氧化鈦薄膜性質之影響 8 1.6.5.退火溫度對二氧化鈦薄膜性質之影響 9 第貳章 理論探討與文獻回顧 11 2.1光觸媒之簡介 11 2.2二氧化鈦之簡介 14 2.2.1.二氧化鈦材料特性 16 2.2.2.二氧化鈦光反應機制 18 2.2.3.二氧化鈦光觸媒特性 20 2.3二氧化鈦薄膜之製備方法 22 2.3.1.液相製備法 22 2.3.2.氣相製備法 23 2.4濺鍍原理 25 2.4.1.直流/射頻濺鍍 26 2.4.2.磁控濺鍍 26 2.4.3.反應性濺鍍 27 2.4.4.薄膜成長理論 28 2.5光觸媒的應用與發展 29 第參章 實驗設計與規劃 31 3.1實驗規劃 31 3.2實驗流程 32 3.3實驗設備 33 3.4薄膜製作 36 3.4.1.基板前處理 36 3.4.2.薄膜濺鍍步驟 37 3.4.3.實驗參數設定 38 3.5薄膜材料特性量測設備 40 3.5.1.薄膜結晶型態量測 40 3.5.2.薄膜表面形貌量測 42 3.5.3.薄膜沉積速率量測 42 3.6薄膜光催化特性量測設備 46 3.6.1.薄膜光學特性量測 46 3.6.2.薄膜親水特性量測 46 3.6.3.亞甲基藍分解實驗 46 3.7太陽能電池鍍膜玻璃之應用測試 49 第肆章 實驗結果與討論 51 4.1製程參數對TiO2光觸媒薄膜特性分析結果 51 4.1.1.薄膜結晶型態分析 51 4.1.2.薄膜表面形貌分析 63 4.1.3.薄膜沉積速率分析 80 4.1.4.薄膜特性評估 85 4.2薄膜光催化特性量測結果與討論 86 4.2.1.薄膜光學特性量測結果 86 4.2.2.薄膜親水特性量測結果 89 4.2.3.亞甲基藍分解實驗量測結果 93 4.2.4.薄膜光催化特性評估 96 4.3太陽能電池鍍膜玻璃之量測結果與討論 97 第伍章 結論與未來展望 101 5.1結論 101 5.2未來展望 103 參考文獻 104 略 傳 113

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