金属栅极功功能工程:亚纳米双栅极mosfet

2019 International Conference on Electrical, Computer and Communication Engineering (ECCE) Pub Date : 2019-02-01 DOI:10.1109/ECACE.2019.8679134

M. Hasan, Kefayet Ullah, M. Hossain, T. Hossain, Nafis Farhan Rashid, Silvee Quraishi, P. Ghosh

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引用次数: 4

摘要

研究了金属栅极(MG)功函数(WF)对双栅极mosfet的影响，为新一代逻辑应用奠定了基础。通过仿真研究了氮化镓双栅mosfet，通过调整功函数(WF)的值来建立传输特性，以减轻ses(短通道效应)。金属栅(MG)功函数(WF)在3.5 eV和4.8 eV之间变化，并对器件性能进行了评价。在多个金属栅(MG)功函数(WF)中观察到ses的降低。仿真结果表明，通过调整氮化镓双栅mosfet的工作函数，可以实现阈值电压的调整。通过确定阈值电压(VT)的合适值，可以减小短通道效应(SCEs)。考虑栅极(LG)长度为9.7 nm (ITRS- Year: 2021)，对gan基dg - mosfet进行了模拟。器件的通断电压(Gate-Source)分别为，VGS = 1v, VGS = 0v。栅极长度为9.7 nm时，有效氧化厚度(EOT)为0.56 nm。在器件仿真中，重点设置在VTH、ION、IOFF、DIBL和SS上，该指标已用于多个金属栅工作功能。通过调整金属栅极的功函数，降低了漏极降低(DIBL)和亚阈值漏电流，提高了阈值电压(VT)。所提出的gan基dg - mosfet表明，可以通过调整MG-WF(金属栅功函数)来减少短通道效应(SCEs)。

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Metal Gate Work Function Engineering: Sub-Nano Regime Double Gate MOSFETs

The effect of metal gate (MG) work function (WF) on MOSFETs having double gate has been researched for the next generation logic applications. GaN-based Double-Gate MOSFETs, by tuning the value of work functions (WF) are investigated by simulation to establish the transport characteristics to mitigate SCEs (short channel effects). The metal gate (MG) work functions (WF) is varied between 3.5 eV and 4.8 eV and the device performance is evaluated. The reduction of SCEs is observed for multiple metal gate (MG) work functions (WF). The simulation results apprise that by tuning the work function of GaN-based double-gate MOSFETs, the threshold voltage tuning can be possible. The reduction of short channel effects (SCEs) can be possible by fixing the congenial value of the threshold voltage (VT). The simulations have been performed for GaN-based DG-MOSFETs considering 9.7 nm (ITRS- Year: 2021) length of the gate (LG). The device turn on and turn off voltage (Gate-Source) is respectively, VGS =1 V and V GS= 0 V. The effective oxide thickness (EOT) is considered as 0.56 nm for a gate length of 9.7 nm. In the device simulation focus has been set on VTH, ION, IOFF, DIBL and SS, this metrics has been done for multiple metal gate work functions. The value of drain induced barrier lowering (DIBL) and subthreshold leakage current is reduced and threshold voltage (VT) is increased with tuning the metal gate work functions. The proposed GaN-based DG-MOSFETs suggests that the reduction of short channel effects (SCEs) can be possible by tuning the MG-WF (metal gate-work function).

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2019 International Conference on Electrical, Computer and Communication Engineering (ECCE)

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