建議

1. 本研究設計上，因實驗所進行常溫常壓電漿輔助法之平板反應器 為壓克力製造，故在反覆抽至負壓後容易造成反應器破裂，所以 之後可改為不銹鋼之材質會有較佳的穩定性。

2. 本研究以常壓電漿輔助奈米微粒製造系統製備觸媒時，僅對部份 參數進行探討，亦可對其他參數例如：不同流量、前驅物與水氣 進流流量比、頻率及電壓大小等一系列參數之探討，將有助於建 立製備觸媒程序之最佳參數。

3. 實驗設計上，本研究進行光催化時並未使用特定光源波長，建議 可改變本身光源之波長，有助於確定可見光光催化程序之操作條 件。

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張君正、張木彬（1994），以介電質放電法處理揮發性有機物之研究，

附錄一

觸媒沈績於玻璃基材之圖片

圖Ⅰ不同製備時間下產生於蓋玻片之照片

(a)製備 2 小時(b) 製備 4 小時(c) 製備 6 小時(d) 製備 8 小時 (載流氣體 N2 & NH3，總流量=198 ccm)

圖Ⅱ不同製備時間下產生於蓋玻片之照片

(a)製備 2 小時(b) 製備 4 小時(c) 製備 6 小時(d) 製備 8 小時 (載流氣體 N2，總流量=198 ccm)

圖Ⅲ不同載流氣體製備觸媒薄膜厚度之圖形

（製備時間6 小時，總流量 198 ccm）

附錄二

觸媒溶解於水中之情形

圖Ⅳ將每毫克觸媒溶於 10 g 水中之情形

(a) 第 1 次製備(b) 第 2 次製備 (c) 第 3 次製備 (d) 第 4 次製備 (e) 第 5 次製備(f) 第 6 次製備