栅极长度对sub - 10nm gan基dg - mosfet的工程影响

2017 IEEE International WIE Conference on Electrical and Computer Engineering (WIECON-ECE) Pub Date : 2017-12-01 DOI:10.1109/WIECON-ECE.2017.8468884

M. Hasan, Muniyat Rafa, M. Hossain, Farah Rafia, M. R. Nidhi

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引用次数: 4

摘要

具有多个栅极长度的氮化镓基dg - mosfet已被设计用于下一代逻辑应用。SILVACO ATLAS已被用于获取非平衡格林函数。设备的通断电压(Gate-Source)分别为$\text{V}_{\mathbf {GS}} =$ 1v (on)和$\textbf{V}_{\mathbf {GS}} =$ 0v (off)。为了从固态器件物理的角度提高高速性能，研究了不同栅极长度对dg - mosfet各种特性的影响。通过改变各种栅极长度($\textbf{L}_{\mathbf {G}} =$ 6 nm至10 nm)来分析器件的影响。器件性能指标，如$\textbf{I}_{\mathbf {ON}}$，亚阈值斜率(SS)和漏极诱导障碍降低(DIBL)已经完成了多个栅极长度。模拟器件验证了基于gan的dg - mosfet的各种栅极长度，适用于下一代高速、高性能(HP)和逻辑应用以及VLSI技术。

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Gate Length Engineering Impact of Sub-10 nm GaN-Based DG-MOSFETs

Gallium nitride based DG-MOSFETs with multiple gate lengths has been designed for the next generation logic applications. SILVACO ATLAS has been used to access Nonequilibrium Green’s function. The device turn on and turn off voltage (Gate-Source) is respectively, $\text{V}_{\mathbf {GS}} =$ 1 V (ON-state) and $\textbf{V}_{\mathbf {GS}} =$ 0 V (OFF-state). To improve high-speed performance from the concept of solid state device physics, effects of changing various characteristics for a different gate length of DG-MOSFETs were studied. Effects of the device are analyzed by varying various gate length ($\textbf{L}_{\mathbf {G}} =$6 nm to 10 nm). The device performance metrics such as $\textbf{I}_{\mathbf {ON}}$, sub threshold slope (SS) and drain induced barrier lowering (DIBL) has been done for multiple gate lengths. The simulated device verifies GaN-based DG-MOSFETs for various gate length for the next generation high speed, high performance (HP) and logic applications and VLSI technology.

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2017 IEEE International WIE Conference on Electrical and Computer Engineering (WIECON-ECE)

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