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| 研究生: |
李俊賢 Chun-Hsien Li |
|---|---|
| 論文名稱: |
負載銀二氧化鈦光觸媒分散及其光催化反應之研究 Dispersion and Impreganating Titania with Nanosized Silver and Its Photocatalytic Property |
| 指導教授: |
周更生
Kan-Sen Chou |
| 口試委員: | |
| 學位類別: |
碩士 Master |
| 系所名稱: |
工學院 - 化學工程學系 Department of Chemical Engineering |
| 論文出版年: | 2004 |
| 畢業學年度: | 92 |
| 語文別: | 中文 |
| 論文頁數: | 77 |
| 中文關鍵詞: | 奈米銀 、二氧化鈦 、光催化反應 |
| 相關次數: | 點閱:3 下載:0 |
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在本論文研究中,首先是將市售之二氧化鈦粉末分散,使其粒子表面積能夠充分展現以提高光催化活性,而經比較後加入界面活性劑Triton X-100比純以超音波震盪的分散效果好,且穩定性也較佳,其中若調整加入界面活性劑後之懸浮液pH值以增強二氧化鈦粒子表面之帶電量,由粒徑儀結果顯示可將原先聚集成3 μm大小之粒子分散至20 nm大小左右,而由對亞甲基藍之光催化測試結果亦証實了經分散過之二氧化鈦粒子有較佳之光催化活性。
接著嘗試著將二氧化鈦粉末沉浸在本實驗室配製之奈米銀溶液中,以化學吸附的方式讓奈米銀自然吸附在二氧化鈦粒子之表面,再試著比較以化學還原奈米銀至二氧化鈦粒子表面之方式,藉著奈米銀可降低電子與電洞對再結合之能力而使二氧化鈦粒子光催化活性提高,而由對亞甲基藍光催化測試結果證實其真實性。然後以高溫氫氣對二氧化鈦粉末做還原的動作,二氧化鈦被還原後會形成部分的Ti3+,藉著Ti3+易抓住電洞的特性延遲電子與電洞對再結合以提升光催化之效果。最後將奈米銀負載於經還原過後之二氧化鈦粒子於紫外光與可見光下對酚作光催化分解,發現其亦得到一定程度的分解效果。
最後將光催化活性得到提升的二氧化鈦粒子以三種不同之覆膜液鍍膜於玻璃基板上,發現以Silicone Rubber作為高分子黏著劑除了可將二氧化鈦粒子緊密地固定於基板上,對亞甲基藍做光催化測試也可得到不錯之分解效果。
In this study, the experiment was divided into three parts. First, we tried to disperse the titania powders in order to enhance the photocatalytic activities via increasing the surface area. Compared with the dispersed titania powders only by ultrasonic vibration, the one added Triton X-100 performed better dispersing result and stability. Moreover, if we adjusted the pH value of suspension after adding Triton X-100, the surface charge of titania powders were enhanced and performed much better dispersing result.
Then we tried to let the nano-silver particles adsorbed onto the surface of titania through chemical adsorption and chemical reduction two methods, and we found that the two ways did enhance the photocatalytic activity of titania by photocatalytic testing on methylene blue solution. The nano-silver particles could reduce the ability of recombination between electron-hole pairs in order to enhance the photocatalytic activity. We also used high-temperature hydrogen gas to reduce some Ti4+ to Ti3+ in the electronic configuration of titania. The photocatalytic activities of titania also improved due to the ability of capturing holes by Ti3+. Finally, we loaded nano-silver particles on titania which had been reduced by high-temperature hydrogen gas, and used them to proceed photocatalytic decomposition reaction on phenol in order to prove its photocatalytic ability.
At last, we coated the titania powders having better photocatalytic activities on the glass substrate by three different kinds of adhesives. Then we found the silicone rubber could fix the titania powders on the glass substrate tightly and perform acceptable results by photocatalytic testing on methylene blue.
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