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引用次数: 0
摘要
研究了40 nm物理栅极长度的锑化铟量子阱场效应晶体管。采用自洽T-CAD仿真研究了InSb场效应晶体管的高速潜力及其适用于高速、极低功耗的逻辑应用。在室温下,电子迁移率超过30,000 cm2/V-1s-1的材料,具有典型的片载流子密度用于模拟晶体管。采用40nm栅极长度可获得6.4e-4A/μm的最大漏极电流,器件的阈值电压为-0.5V。当掺杂浓度为1e+19时,最大漏极电流为6.4e-4。当栅极电压超过0.2V时,器件的OFF电流为2.6420 -07 a /μm。
Modelling and investigation of III-V compound semiconductor based HEMT's for high performance applications
This paper investigates indium antimonide based quantum well field effect transistors with 40 nm physical gate length. Self consistent T-CAD simulations are used to study the high-speed potential of InSb field-effect transistors and its suitable for high speed, very low power logic applications. At the room temperature electron mobility in excess of 30,000 cm2/V-1s-1 in material with sheet carrier density typical of that employed in analogue transistors. 40nm gate length is used to obtain maximum drain current of 6.4e-4A/μm and the threshold voltage of the device is found to be -0.5V. The maximum drain current is found to be 6.4e-4 for the doping concentration of 1e+19. The OFF current of the device is found to be 2.642e-07A/μm when the gate voltage increases beyond 0.2V.
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