Innovative Spacer material integration in Tree-FETs for enhanced performance across Variable channel lengths

IF 2.7 Q2 PHYSICS, CONDENSED MATTER
Dharavath Parvathi, P Prithvi
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引用次数: 0

Abstract

This work presents a novel three-channel Tree-FET optimized for superior DC and analog performance metrics. The device structure features nanosheets with a width (NSWD) of 9 nm, a thickness (NSTH) of 5 nm, and interbidge dimensions of 8 nm in height (IBHT) and 5 nm in width (IBWD). The Tree-FET demonstrates an exceptional on/off current ratio of 107 through meticulous engineering, significantly outperforming conventional FET configurations. Our comprehensive study explores the effects of different spacer materials, including HfO2, Al2O3, Si3N4, and SiO2, across varied channel lengths. The superior dielectric properties of HfO2 contribute to fine-tuning the device's characteristics, making it a standout choice for optimizing performance. Out of all HfO2 has been found to perform exceptionally well, offering the best combination of electrostatic control and minimized leakage currents. Because the Tree-FET has better electrostatic integrity and can keep working well with different spacer materials and channel lengths, it has much potential as a flexible and valuable part for next-generation semiconductor devices. The promising DC and analog metrics achieved through this novel design pave the way for developing more compact, high-performance electronic components.

在树型场效应晶体管中集成创新的间隔材料,以提高不同沟道长度的性能
这项研究提出了一种新型三沟道树型场效应晶体管(Tree-FET),该器件经过优化,具有卓越的直流和模拟性能指标。该器件结构的纳米片宽度(NSWD)为 9 nm,厚度(NSTH)为 5 nm,桥间尺寸高度(IBHT)为 8 nm,宽度(IBWD)为 5 nm。通过精心设计,树状场效应晶体管的导通/关断电流比高达 107,大大优于传统的场效应晶体管配置。我们的综合研究探讨了不同间隔材料(包括 HfO2、Al2O3、Si3N4 和 SiO2)对不同沟道长度的影响。HfO2 优越的介电特性有助于微调器件的特性,使其成为优化性能的最佳选择。在所有器件中,HfO2 的性能尤为出色,是静电控制和漏电流最小化的最佳组合。由于树型场效应晶体管具有更好的静电完整性,并能在使用不同的间隔材料和沟道长度时保持良好的工作状态,因此它作为下一代半导体器件的灵活而有价值的部件具有很大的潜力。通过这种新颖设计实现的直流和模拟指标前景广阔,为开发更紧凑、更高性能的电子元件铺平了道路。
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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CiteScore
6.50
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