超短沟道绝缘层上硅平面场效应晶体管中热载流子注入应力导致的退化对沟道长度的依赖性

刘畅; 卢继武; 吴汪然; 唐晓雨; 张睿; 俞文杰; 王曦; 赵毅

doi:10.7498/aps.64.167305

摘要

随着场效应晶体管(MOSFET)器件尺寸的进一步缩小和器件新结构的引入, 学术界和工业界对器件中热载流子注入(hot carrier injections, HCI)所引起的可靠性问题日益关注. 本文研究了超短沟道长度(L=30–150 nm)绝缘层上硅(silicon on insulator, SOI)场效应晶体管在HCI应力下的电学性能退化机理. 研究结果表明, 在超短沟道情况下, HCI 应力导致的退化随着沟道长度变小而减轻. 通过研究不同栅长器件的恢复特性可以看出, 该现象是由于随着沟道长度的减小, HCI应力下偏压温度不稳定性效应所占比例变大而导致的. 此外, 本文关于SOI器件中HCI应力导致的退化和器件栅长关系的结果与最近报道的鳍式场效晶体管(FinFET)中的结果相反. 因此, 在超短沟道情况下, SOI平面MOSFET器件有可能具有比FinFET器件更好的HCI可靠性.

关键词:

Abstract

With the continued device scaling and the introduction of new device structures, MOSFET reliability phenomena arising from the hot carrier injection (HCI) stress have received extensive attention from both the academia and the industry community. In this work, the degradations of ultra-scaled silicon on insulator (SOI) MOSFETs under the HCI stress are investigated on devices of different gate lengths (L=30-150 nm). Our experimental data demonstrate that the time evolutions of the threshold voltage change (Vth) under the HCI stress for different gate length devices are the same, and the magnitude of Vth reduces for the shorter devices. The degradation of the device under the HCI stress should be due to both the channel hot carrier (CHC) effect and the bias temperature instability (BTI) effect. The distribution and magnitude of the electric field along the MOSFET's channel are analyzed. It is confirmed that besides the well-known CHC effect in the depletion region close to the drain side, a strong BTI effect co-exists in the channel close to the source side. This degradation mechanism is different from the conventional HCI stress. With the gate length decreasing, the contribution of the aforementioned BTI effect becomes larger, and it dominates in the degradation. One feature of the BTI effects is that the corresponding degradation is small when the gate length is short. This is consistent with our experimental result that the change of Vth is small for the device of short gate length under the accelerated HCI stress. The time evolution of Vth can be described by the equation Vth=A•tn, where A is a constant, t is the stress time, and n is the power law exponent obtained by the curve fitting. In this study, the power law exponent n of pMOSFET is larger than that of nMOSFET. This experimental fact can lead to the point that the BTI effect exists during the HCI stress because the BTI effect in ultra-scaled pMOSFETs is more significant than that in nMOSFETs. The stress-recover experiments of the HCI stress on MOSFTTs show larger recovery in device of shorter gate length. It is found that the ratio of the recovery to the total degradation in the 30 nm gate-length device is almost twice as large as that in the 150 nm device. The degradation from the CHC effect has no recovery, and the larger recovery in the shorter-channel device implies the larger component of the BTI degradation. Another intriguing fact is that our experimental result on SOI MOSFET is inconsistent with the recently reported result on FinFET. We argue that the reported stronger HCI degradation in FinFET may not be ascribed only to the stronger electric field in the shorter channel, but also to the fact that the FinFET' channel is three-dimensionally surrounded by the gate dielectric. This kind of three-dimensional structure significantly increases the chance for electrons or holes to be injected into the dielectric layer. Therefore the HCI reliability of planar SOI MOSFETs may be better than that of FinFETs at the same level of gate length. In conclusion, the BTI effect is an important source of the degradation during the HCI stress in ultra-short-channel device, and it is no more negligible in analyzing the underlying physical mechanism.

Keywords:

silicon on insulator /
metal-oxide semiconductor field effect transistor /
hot carrier injection /
gate length

作者及机构信息

1.
南京大学电子科学与工程学院, 南京 210093;

2.
浙江大学信息与电子工程学系, 杭州 310027;

3.
中国科学院上海信息技术与微系统研究所, 上海 200050;

4.
浙江大学硅材料国家重点实验室, 杭州 310027

基金项目: 国家重点基础研究发展规划(批准号: 2011CBA00607)、国家自然科学基金(批准号: 61376097)、浙江省自然科学基金(批准号: LR14F040001)和功能信息材料国家重点实验室开放课题(批准号: SKL201304)资助的课题.

Authors and contacts

1.
School of Electronic Science and Engineering, Nanjing University, Nanjing 210093, China;

2.
Department of Information Science and Electronic Engineering, Zhejiang University, Hangzhou 310027, China;

3.
Shanghai Institute of Microsystem and Information Technology, Chinese Academy of Sciences, Shanghai 200050, China;

4.
State Key Laboratory of Silicon Materials, Zhejiang Unviersity, Hangzhou 310027, China

Funds: Project supported by the National Basic Research Program of China (Grant No. 2011CBA00607), the National Natural Science Foundation of China (Grant No. 61376097), the Natural Science Foundation Zhejiang Province of China (Grant No. LR14F040001), and the Open Project of State Key Laboratory of Functional Materials for Informatics, China (Grant No. SKL201304).

参考文献

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[5]	Ma X H, Cao Y R, Hao Y, Zhang Y 2011 Chin. Phys. B 20 037305
[6]	Lei X Y, Liu H X, Zhang K, Zhang Y, Zheng X F, Ma X H, Hao Y 2013 Chin. Phys. B 22 047304
[7]	Wu W R, Liu C, Sun J B, Yu W J, Wang X, Shi Y, Zhao Y 2014 IEEE Electron Dev. Lett. 35 714
[8]	Miura Y, Matukura Y 1966 Jpn. J. Appl. Phys. 5 180
[9]	Ning T H, Cook P W, Dennard R H, Osburn C M, Schuster S E, Yu H N 1979 IEEE Trans. Electron Dev. 26 346
[10]	Amat E, Kauerauf T, Rodriguez R, Nafria M, Aymerich X, Degraeve R, Groeseneken G 2013 Microelectron. Eng. 103 144
[11]	Franco J, Kaczer B, Eneman G, Roussel P, Cho M, Mitard J, Witters L, Hoffmann T Y, Groeseneken G, Crupi F, Grasser T 2011 IEEE International Reliability Physics Symposium Monterey, CA, United States, April 10-14, 2011 p6A.4.1
[12]	Ramey S, Hicks J, Liyanage L S, Novak S 2014 IEEE International Reliability Physics Symposium Waikoloa, HI, United States, June 1-5, 2014 pXT.2.1
[13]	Ramey S, Ashutosh A, Auth C, Clifford J, Hattendorf M, Hicks J, James R, Rahman A, Sharma V, Amour St A, Wiegand C 2013 IEEE International Reliability Physics Symposium Monterey, CA, United States, April 14-18, 2013 p4C.5.1
[14]	Takeda E, Suzuki N 1983 IEEE Electron Dev. Lett. 4 111
[15]	Duan F, Ioannou D 1996 SOI Conference, 1996 Proceedings, 1996, IEEE International p18
[16]	Doyle B S, Mistry K R, Faricelli J 1997 IEEE Electron Dev. Lett. 18 51
[17]	Amat E, Kauerauf T, Degraeve R, Rodriguez R, Nafria M, Aymerich X, Groeseneken G 2009 IEEE Trans. Electron Dev. 9 454
[18]	Angot D, Huard V, Federspiel X, Cacho F, Bravaix A 2013 IEEE International Reliability Physics Symposium Anaheim, CA, United States, April 14-18,2013 p5D.2.1
[19]	Liao J C, Fang Y K, Hou Y T, Hung C L, Hsu P F, Lin K C, Huang K T, Lee T L, Liang M S 2008 Appl. Phys. Lett. 93 092101
[20]	Alam M, Mahapatra S 2005 Microelectron. Reliab. 45 71

施引文献

[1]	Liu S E, Wang J S, Lu Y R, Huang D S, Huang C F, Hsieh W H, Lee J H, Tsai Y S, Shih J R, Lee Y H, Wu K 2014 IEEE International Reliability Physics Symposium Waikoloa, HI, United States, June 1-5, 2014 p4A.4.1
[2]	Zhao Y, Wan X G 2006 Acta Phys. Sin. 55 3003 (in Chinese) [赵毅, 万星拱 2006 55 3003]
[3]	Liang B, Chen J J, Chi Y Q 2014 Chin. Phys. B 23 117304
[4]	Chen J J, Chen S M, Liang B, He Y B, Chi Y Q, Deng K F 2011 Chin. Phys. B 20 114220
[5]	Ma X H, Cao Y R, Hao Y, Zhang Y 2011 Chin. Phys. B 20 037305
[6]	Lei X Y, Liu H X, Zhang K, Zhang Y, Zheng X F, Ma X H, Hao Y 2013 Chin. Phys. B 22 047304
[7]	Wu W R, Liu C, Sun J B, Yu W J, Wang X, Shi Y, Zhao Y 2014 IEEE Electron Dev. Lett. 35 714
[8]	Miura Y, Matukura Y 1966 Jpn. J. Appl. Phys. 5 180
[9]	Ning T H, Cook P W, Dennard R H, Osburn C M, Schuster S E, Yu H N 1979 IEEE Trans. Electron Dev. 26 346
[10]	Amat E, Kauerauf T, Rodriguez R, Nafria M, Aymerich X, Degraeve R, Groeseneken G 2013 Microelectron. Eng. 103 144
[11]	Franco J, Kaczer B, Eneman G, Roussel P, Cho M, Mitard J, Witters L, Hoffmann T Y, Groeseneken G, Crupi F, Grasser T 2011 IEEE International Reliability Physics Symposium Monterey, CA, United States, April 10-14, 2011 p6A.4.1
[12]	Ramey S, Hicks J, Liyanage L S, Novak S 2014 IEEE International Reliability Physics Symposium Waikoloa, HI, United States, June 1-5, 2014 pXT.2.1
[13]	Ramey S, Ashutosh A, Auth C, Clifford J, Hattendorf M, Hicks J, James R, Rahman A, Sharma V, Amour St A, Wiegand C 2013 IEEE International Reliability Physics Symposium Monterey, CA, United States, April 14-18, 2013 p4C.5.1
[14]	Takeda E, Suzuki N 1983 IEEE Electron Dev. Lett. 4 111
[15]	Duan F, Ioannou D 1996 SOI Conference, 1996 Proceedings, 1996, IEEE International p18
[16]	Doyle B S, Mistry K R, Faricelli J 1997 IEEE Electron Dev. Lett. 18 51
[17]	Amat E, Kauerauf T, Degraeve R, Rodriguez R, Nafria M, Aymerich X, Groeseneken G 2009 IEEE Trans. Electron Dev. 9 454
[18]	Angot D, Huard V, Federspiel X, Cacho F, Bravaix A 2013 IEEE International Reliability Physics Symposium Anaheim, CA, United States, April 14-18,2013 p5D.2.1
[19]	Liao J C, Fang Y K, Hou Y T, Hung C L, Hsu P F, Lin K C, Huang K T, Lee T L, Liang M S 2008 Appl. Phys. Lett. 93 092101
[20]	Alam M, Mahapatra S 2005 Microelectron. Reliab. 45 71

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