纳米片
材料科学
退火(玻璃)
光电子学
晶体管
薄脆饼
场效应晶体管
离子
纳米技术
电子工程
电压
电气工程
化学
冶金
工程类
有机化学
作者
Sanguk Lee,Jinsu Jeong,Bohyeon Kang,Seunghwan Lee,Junjong Lee,Jaewan Lim,Hyeonjun Hwang,Sung–Min Ahn,Rock‐Hyun Baek
出处
期刊:Nanomaterials
[Multidisciplinary Digital Publishing Institute]
日期:2023-02-26
卷期号:13 (5): 868-868
被引量:4
摘要
This study proposed a novel source/drain (S/D) extension scheme to increase the stress in nanosheet (NS) field-effect transistors (NSFETs) and investigated the scheme by using technology-computer-aided-design simulations. In three-dimensional integrated circuits, transistors in the bottom tier were exposed to subsequent processes; therefore, selective annealing, such as laser-spike annealing (LSA), should be applied. However, the application of the LSA process to NSFETs significantly decreased the on-state current (Ion) owing to diffusionless S/D dopants. Furthermore, the barrier height below the inner spacer was not lowered even under on-state bias conditions because ultra-shallow junctions between the NS and S/D were formed far from the gate metal. However, the proposed S/D extension scheme overcame these Ion reduction issues by adding an NS-channel-etching process before S/D formation. A larger S/D volume induced a larger stress in the NS channels; thus, the stress was boosted by over 25%. Additionally, an increase in carrier concentrations in the NS channels improved Ion. Therefore, Ion increased by approximately 21.7% (37.4%) in NFETs (PFETs) compared with NSFETs without the proposed scheme. Additionally, the RC delay was improved by 2.03% (9.27%) in NFETs (PFETs) compared with NSFETs using rapid thermal annealing. Therefore, the S/D extension scheme overcame the Ion reduction issues encountered in LSA and significantly enhanced the AC/DC performance.
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