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四层垂直堆叠水平环绕栅硅纳米片器件的结构与电学特性优化

Optimization of Structure and Electrical Characteristics for Four-Layer Vertically-Stacked Horizontal Gate-All-Around Si Nanosheets Devices.

作者信息

Zhang Qingzhu, Gu Jie, Xu Renren, Cao Lei, Li Junjie, Wu Zhenhua, Wang Guilei, Yao Jiaxin, Zhang Zhaohao, Xiang Jinjuan, He Xiaobin, Kong Zhenzhen, Yang Hong, Tian Jiajia, Xu Gaobo, Mao Shujuan, Radamson Henry H, Yin Huaxiang, Luo Jun

机构信息

Advanced Integrated Circuits R&D Center, Institute of Microelectronic of the Chinese Academy of Sciences, Beijing 100029, China.

Key Laboratory of Microelectronics Devices and Integrated Technology, Institute of Microelectronics, CAS, Beijing 100029, China.

出版信息

Nanomaterials (Basel). 2021 Mar 5;11(3):646. doi: 10.3390/nano11030646.

DOI:10.3390/nano11030646
PMID:33808024
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7998492/
Abstract

In this paper, the optimizations of vertically-stacked horizontal gate-all-around (GAA) Si nanosheet (NS) transistors on bulk Si substrate are systemically investigated. The release process of NS channels was firstly optimized to achieve uniform device structures. An over 100:1 selective wet-etch ratio of GeSi to Si layer was achieved for GeSi/Si stacks samples with different GeSi thickness (5 nm, 10 nm, and 20 nm) or annealing temperatures (≤900 °C). Furthermore, the influence of ground-plane (GP) doping in Si sub-fin region to improve electrical characteristics of devices was carefully investigated by experiment and simulations. The subthreshold characteristics of -type devices were greatly improved with the increase of GP doping doses. However, the -type devices initially were improved and then deteriorated with the increase of GP doping doses, and they demonstrated the best electrical characteristics with the GP doping concentrations of about 1 × 10 cm, which was also confirmed by technical computer aided design (TCAD) simulation results. Finally, 4 stacked GAA Si NS channels with 6 nm in thickness and 30 nm in width were firstly fabricated on bulk substrate, and the performance of the stacked GAA Si NS devices achieved a larger / ratio (3.15 × 10) and smaller values of Subthreshold swings (s) (71.2 (N)/78.7 (P) mV/dec) and drain-induced barrier lowering (s) (9 (N)/22 (P) mV/V) by the optimization of suppression of parasitic channels and device's structure.

摘要

在本文中,系统地研究了体硅衬底上垂直堆叠的水平全栅(GAA)硅纳米片(NS)晶体管的优化。首先对NS沟道的释放工艺进行了优化,以实现均匀的器件结构。对于不同GeSi厚度(5nm、10nm和20nm)或退火温度(≤900°C)的GeSi/Si堆叠样品,实现了GeSi与Si层超过100:1的选择性湿法蚀刻比。此外,通过实验和模拟仔细研究了硅子鳍区域中的接地平面(GP)掺杂对改善器件电学特性的影响。随着GP掺杂剂量的增加,n型器件的亚阈值特性得到了极大改善。然而,p型器件最初随着GP掺杂剂量的增加而改善,然后恶化,并且在GP掺杂浓度约为1×10¹⁸cm⁻³时表现出最佳电学特性,这也得到了技术计算机辅助设计(TCAD)模拟结果的证实。最后,首次在体衬底上制造了4个堆叠的厚度为6nm、宽度为30nm的GAA硅NS沟道,并且通过优化寄生沟道抑制和器件结构,堆叠的GAA硅NS器件的性能实现了更大的Ion/Ioff比(3.15×10⁷)以及更小的亚阈值摆幅(SS)值(n型为71.2mV/dec,p型为78.7mV/dec)和漏极诱导势垒降低(DIBL)值(n型为9mV/V,p型为22mV/V)。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e0ce/7998492/c7671cbadbec/nanomaterials-11-00646-g012.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e0ce/7998492/aad1b8f0827d/nanomaterials-11-00646-g007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e0ce/7998492/89e0e588c182/nanomaterials-11-00646-g008.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e0ce/7998492/d6cee81c954b/nanomaterials-11-00646-g009.jpg
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