Improving on current using new double-material heterojunction gate all around TFET (DMHJGAA TFET): Modeling and simulation

IF 1.4 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
P. Vimala, N. Shree, U. Priyadarshini, T. Samuel
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引用次数: 1

Abstract

Transistor, which is the building block of all electronic devices, has continuously scaled down its dimensions for better efficiency since the advent of CMOS circuits. Due to the thermal limit on the switching and various short-channel effects (SCEs), highly scaled MOSFETs are rendered unusable for low-power applications. Hence, the Tunnel Field-Effect Transistors (TFETs) are studied extensively for ultra-low-power applications. Further, multigate TFETs have emerged as the prime candidates for achieving better gate controllability. Throughout this work, a newly revised analytical model for Heterojunction Gate All Around (HJGAA) TFET is demonstrated using a 2D parabolic approximation equation. Analytical expressions are derived for both potential distribution and field distribution using appropriate boundary conditions. This distribution of electric fields is further used to measure the rate of tunneling output, and then we have extracted the drain current numerically. The findings indicate a substantial change in the drain current characteristics while reducing the SCE impacts to a considerable amount. Feasibility of the newly updated model is verified by comparing the results of the analytical model with the results of TCAD simulator.
利用新型双材料异质结栅极改善TFET (DMHJGAA TFET)的电流:建模与仿真
晶体管是所有电子设备的组成部分,自CMOS电路出现以来,晶体管一直在不断缩小尺寸以提高效率。由于开关的热限制和各种短沟道效应(SCE),高规模MOSFET无法用于低功率应用。因此,隧道场效应晶体管(TFET)被广泛研究用于超低功率应用。此外,多栅极TFET已经成为实现更好的栅极可控性的主要候选者。在整个工作中,使用2D抛物型近似方程演示了异质结门全方位(HJGAA)TFET的新修订的分析模型。利用适当的边界条件导出了电势分布和场分布的解析表达式。这种电场分布被进一步用于测量隧道输出的速率,然后我们用数值方法提取了漏极电流。研究结果表明,漏极电流特性发生了实质性变化,同时将SCE影响降低到相当大的程度。通过将分析模型的结果与TCAD模拟器的结果进行比较,验证了新更新模型的可行性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
2.10
自引率
15.40%
发文量
27
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