製作Nano-structures(80~500nm)元件以形成區域發光體來改善元件之發光效率,其主要應用與發光二極體(LED)類似,而由於其發光效率可被提升30~50%,故一直是項熱門的研究題目。本研究主要以氮化鎵等III-V族化合物半導體為發光材料,再利用e-beam lithography方式製成發光元件。接著以質子佈植或蝕刻(etching)法以做成區域發光之Nano-structure devices。為利用Nano-structures 來促進發光元件之發光效率,所以首先利用電子束微影技術來製作所設計之奈米結構元件。更進一步利用離子佈植技術,將具有不同載子濃度之原生n 型或p型氮化鎵薄膜,以不同劑量及能量來佈植氫離子。再經熱退火處理後,希望能提高轉質後之個別區域發光體之電隔絕效應,來製作高發光效率之氮化鎵發光二極體。接著量測與分析此元件之直流及光特性,並對於奈米微影技術及p-n界面之光性與電性量測及其物理機制亦將深入探討研究。本計畫所包含之技術有:1.離子佈植技術,2. 奈米元件製作及量測技術,3. p-n二極體技術,4.氮化鎵之高效率發光元件。 Nano-structured compound semiconductors have recently attracted considerable interest due to their application for the enhanced quantum efficiency of optoelectronic devices. The enhanced light-extraction of individual light-emitting materials, fabricated by nano-structures, were compared with the conventional LEDs. Electron-beam lithographic pattering and proton implantation are used to fabricate these nano-structure devices. Device characteristics, such as the current-voltage characteristics, light output power, will be measured and compared with those conventional LEDs. 研究期間:9201 ~ 9212
