不同通道长度对新型 n 型硅基 DG-JLT 模拟/射频性能的影响

IF 2.7 Q2 PHYSICS, CONDENSED MATTER
Rohan Ghosh, Shriyans Roy, Ayush Kashyap, Atanu Kundu
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引用次数: 0

摘要

由于短沟道效应和漏电,不断缩小的 MOSFET 性能受到影响。无结晶体管 JLT 因其更简单的制造工艺和更好的栅极控制而成为有前途的替代品。本文研究了具有不同沟道长度(15 nm、20 nm 和 25 nm)的 n 型硅基双栅无结晶体管的模拟和射频性能特性。这项研究通过漏极电流密度 (Id)、跨导 (gm)、输出电阻 (RO)、本征增益 (gmRO) 和跨导生成因子 (gm/Id) 等关键参数来评估模拟器件的性能。这些参数评估了电流处理、增益特性和设计效率,为模拟电路应用提供了全面的分析。结果表明,沟道长度为 15 nm 的器件的跨导比 20 nm 的器件高 25.38%,漏极电流比后者高 44.7%,表明其性能优于沟道长度更长的器件。此外,还利用器件的小信号模型评估了器件的射频性能。这项工作利用关键性能指标(FoMs)进一步研究了器件的高频响应:栅极电容(Cgs、Cgd、Cgg)、截止频率(fT)和最大振荡频率(fMAX)。这些参数量化了寄生电容对开关速度以及模拟和射频应用最大可用频率的影响。对 Cgs、Cgd 和 Cgg 的分析揭示了栅极控制对高频操作的影响。与 20 nm 沟道长度的器件相比,15 nm 沟道长度的器件 fT 提高了 47.29%,fMAX 提高了 68.97%。研究结果强调了优化沟道长度对提高 n 型硅基双栅无结晶体管的模拟和射频性能的重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Impact of varying channel length on Analog/RF performances in a novel n-type silicon-based DG-JLT

Shrinking MOSFETs suffer performance hits due to short-channel effects and leakage. Junctionless transistors JLTs emerge as promising alternatives due to simpler fabrication and better gate control. This paper investigates the analog and RF performance characteristics of n-type Silicon-Based Double Gate Junctionless Transistors with varying channel lengths (15 nm, 20 nm, and 25 nm) This study evaluates analog device performance through critical parameters: drain current density (Id), transconductance (gm), output resistance (RO), intrinsic gain (gmRO), and transconductance generation factor (gm/Id). These parameters assess current handling, gain characteristics, and design efficiency, providing a comprehensive analysis for analog circuit applications. Results indicate that the device having 15 nm channel length exhibits a transconductance which is 25.38 % more than the 20 nm variant and drain current which is 44.7 % more than the latter, suggesting its superior performance to devices with longer channel lengths. In addition, the RF performance of the devices is evaluated using the small signal model of the device. This work further investigates the high-frequency response of the devices using key figures of merit (FoMs): gate capacitances (Cgs, Cgd, Cgg), cut-off frequency (fT), and maximum oscillation frequency (fMAX). These parameters quantify the influence of parasitic capacitances on switching speed and the maximum useable frequency for analog and RF applications. Analyzing Cgs, Cgd, and Cgg reveals the impact of gate control on high-frequency operation. The device having 15 nm channel length, exhibits an increase of 47.29 % in fT and 68.97 % increase in fMAX compared to device having 20 nm channel length. The findings underscore the significance of channel length optimization in enhancing the Analog and RF performance of n-type Silicon-based Double Gate Junctionless Transistors.

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