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研究生: 林宜憲
Lin, Yi-Hsien
論文名稱: 應用於超低功率互補式傾斜閘極穿隧場效電晶體之設計
Design of Complementary Tilt-Gate Tunneling Field Effect Transistor for Ultra-Low-Power Applications
指導教授: 劉傳璽
Liu, Chuan-Hsi
莊紹勳
Chung, Shao-Shiun
學位類別: 碩士
Master
系所名稱: 機電工程學系
Department of Mechatronic Engineering
論文出版年: 2015
畢業學年度: 103
語文別: 中文
論文頁數: 85
中文關鍵詞: 穿隧場效電晶體最大電場半導體模擬工具異質接面
英文關鍵詞: Tunnel FET, Maximum Electric Field, TCAD, Heterojunction
論文種類: 學術論文
相關次數: 點閱:119下載:7
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  • 基於物理限制的原因,金氧半場效電晶體(Metal-Oxide-Semiconductor Field Effect Transistor, MOSFET)的次臨界擺幅無法低於60 mV/decade,使操作電壓Vdd無法持續往下微縮。穿隧型場效電晶(Tunnel Field Effect Transistor, TFET)近期受到許多研究團隊關注,由於不用同於金氧半場效電晶體操作機制,它是利用能帶至能帶的穿隧(Band-to-Band Tunneling),因此能夠擁有低於60 mV/decade的次臨界擺幅,有利於操作電壓Vdd的微縮。
    在本論文的研究,我們提出最大電場與最大能帶至能帶穿隧機率有相當的關聯性,以促使穿隧型場效電晶體元件性能進一步提升,利用半導體模擬工具 (Technology Computer Aided Design, TCAD)來應證。本文成功設計出穿隧電晶體由pTFET為矽鍺與矽、nTFET為砷化銦與銻化鎵所組成的互補式架構,且元件結構能使最大電場與最大能帶至能帶穿隧機率對齊,使穿隧機率大幅提升。模擬結果顯示在閘極形成一個鈍角的結構並搭配異質接面的方式,能使得元件相較於平面能有4個數量級的驅動電流值提升。最後,本研究的互補式傾斜閘極穿隧電晶體元件在適當角度的閘極結構下,能取代互補式金屬氧化半導體元件在低操作功率(Low Operation Power, LOP)及低待機功率(Low Standby Power, LSTP)操作狀態下的元件。

    Due to the physical limitation, the sub-threshold swing (S.S.) of Metal-Oxide-Semiconductor Field Effect Transistors (MOSFETs) can not be below 60 mV/decade, which limits the scaling of the operation voltage (Vdd). Tunneling FETs (TFETs) have been attracted much more attention because Zener band-to-band tunneling (B2BT) allows S.S. smaller than 60 mV/decade, and hence Vdd can be accordingly scaled down.
    In this research, we have proposed a new engineering concept for alignment between the maximum band-to-band tunneling rate and electric field that was designed to enhance the performance of TFETs, which has been demonstrated by Technology Computer Aided Design (TCAD). The structures of hetero junctions for pTFETs and nTFETs are SiGe/Si and InAs/GaSb, respectively. A novel structure of Tilt-Gate TFET has been introduced to increase the B2B tunneling probability by the exact alignment between maximum electric field and maximum B2BT rate. It was found that if the gate of TFET is formed an obtuse shape, the on-current can be dramatically improved by 4 orders in comparison with the planar transistors. Therefore, Tilt complementary TFET has been constructed and with its potential to replace the CMOS devices in LOP and LSTP applications by suitable design of the gate structure in the new design.

    第一章 緒論 1 1.1 研究背景與動機 1 1.2 本論文研究流程與架構 2 第二章 文獻回顧與理論探討 3 2.1金氧半場效電晶體微縮下的瓶頸 3 2.2穿隧型場效電晶體 8 2.2.1基礎穿隧理論 8 2.3.2穿隧電晶體操作機制 9 2.3.3穿隧電晶體基本特性與性能優化 12 2.3.3.1性能優化設計 14 2.3邊角效應探討 27 2.4 TCAD模擬軟體簡介 30 2.2.1工作平台 30 2.3.2元件結構編輯工具 31 2.4.3穿隧電晶體電特性模擬工具 32 第三章 平面型穿隧電晶體元件特討探討及優化 33 3.1 傳統平面元件特性探討 33 3.2 平面型異質接面穿隧電晶體元件特性探討及優化 43 3.2.1矽-矽鍺穿隧電晶體元件特性探討 43 3.2.2三五族穿隧電晶體元件特性探討 44 第四章 傾斜式閘極穿隧電晶體之元件設計與優化 51 4.1 不同結構對元件特性之影響 51 4.2元件參數優化設計 58 4.3傾斜式閘極穿隧電晶體元件製備 68 4.4不同角度的傾斜式閘極穿隧電晶體之電流特性影響 70 4.5雙閘極結構對傾斜式閘極穿隧電晶體的影響 76 第五章 總結與未來展望 81 5.1 穿隧電晶體特性 81 5.2 未來展望 82 參考文獻 83  

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