對稱之一維光子晶體複合結構週期數 m 從 1 增至 4,缺陷模態的穿透峰越 2005 年,由 Subramanian 教授的研究團隊使利用玻璃層夾空氣層製作一維 光子晶體,並在 10 至 20 GHz 的範圍內,探討空氣層的厚度對於光子能隙
表 5.1 不同一維光子晶體結構特性整理表。
授研究團隊在測定電場作用下液晶分子的應答時間時,其液晶盒為毫米級 厚度 [63];又如美國中佛大(University of Central Florida)的吳詩聰教授研 究團隊於 2012 年也製作出具有毫米級厚度之液晶盒,並測量其在電場中的
2. 毫米波的部分雖已有基本的液晶傾角資料庫,但資料庫範圍不夠大,因 此必須擴大範圍,使模擬的準確性提高。此外,光譜波段尺度可再精細 化。
具有光子能隙的光子晶體可應用於諸多光學元件,如波導、光學膜、反 射鏡、光開關、通道分波器、波長分割多工器(wave division multiplxers), 抗反射鍍膜等。一維光子晶體的應用不僅只在可見光及毫米波段,紅外通訊 及太赫茲頻段之一維光子晶體的應用研究正方興未艾,因此,將本文所述一 維光子晶體光學模擬程式擴大,使其涵蓋可見光波至毫米波段為未來值得 投入的工作。如此一來,本團隊在可調控一維光子晶體的研究成果將更加豐 盛。
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