2016-01-012024-05-17https://scholars.lib.ntu.edu.tw/handle/123456789/679347摘要：藉由本計劃中其他子計劃之優異的長晶技術與量測分析能力，在此子計劃中，我們將設計新穎奈米複合半導體材料，並研究其物理特性，由於奈米複合半導體具有很大的界面面積，複合材料間的耦合作用力將會很大，因而會產生有別於各個獨自物體的奇特現象特性。在此子計畫中，我們擬訂的研究主題將包括 (一)複合生物與奈米半導體光電元件(二)複合奈米半導體之電學特性(三)高效率半導體奈米複合物光電元件(四)複合磁性與III-V半導體奈米材料(五)複合二維材料與III-V半導體奈米材料。我們的計畫包含研究世界上最尖端複合奈米材料，而且與低維度電子系統整合，相信可以觀察到有趣的物理現象進而解答一些懸而未決的重要議題如複合奈米系統的耦合機制，低維度電子系統傳輸機制，乃至室溫之磁電效應等，這些結果將有利於發展高效能與綠元件。<br> Abstract: With the excellent growth and characterization techniques of the subprojects in this proposal, in this subproject we will design novel nanocomposites based on compound semiconductors and investigate their unique properties. Due to the inherent nature of a large interface area of nanocomposite systems, there exists a strong coupling strength, which can generate new physical properties in our designed systems. Here, the main topics will be focused on (1) biologically inspired optoelectronic devices based on semiconductor nanostructures. (2) electrical properties of novel semiconductor nanocomposites. (3)high performance optoelectronic devices made with semiconductor nanocomposites. (4) hybrid magnetic film and nanoscale compound semiconductors (5) hybrid two dimensional materials and nanoscale compound semiconductors. We will investigate probably the most frontier nanocomposite materials in the world, which combine the interesting nanomaterial systems with low dimensional electron systems. We believe that we will be able to observe unique physical effects and may answer some important issues, such as coupling between hybrid nanosystems, transport mechanism of low dimensional systems, and magneto-electric effect at room temperature, and so forth. They will be very useful to create high performance and green devices.奈米半導體複合物光電元件低維度材料。hybrid semiconductor nanomaterialsoptoelectronic devicelow dimensional materials.