未來展望

1. 經過多次擴孔、陽極氧化可以製作出其他形狀的氧化膜，對於將 其當作模板可合成其他形狀的奈米級粒子、線，以及利用光導通 現象製作出光學元件。

2. 針對不同金屬如具有二價自由電子金屬:銅，可進行類似的實驗，

探討自由電子數量在光學激發的行為上扮演何種角色

3. 雖然經過一系列的實驗，但對於其反應機制還不是很透徹，如表 面電漿共振起始、轉換的時間等等，需借助 PL、時間解析(Time Result)分析系統來達成此目的

4. 目前我們只使用白光(非極化)來觀察，未來可再增加 P-polarize、

S-polarize 條件觀察，看是否能觀察到第二共振點，甚至於負向 折射係數

110

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