The damage effect and mechanism of the bipolar transistor caused by microwaves

Ma Zhen-Yang; Chai Chang-Chun; Ren Xing-Rong; Yang Yin-Tang; Chen Bin

doi:10.7498/aps.61.078501

Abstract

Combining self-heating effect, mobility degradation in high electric field and avalanche generation effect, a two-dimensional electro-thermal model of the typical silicon-based n+-p-n-n+ structure bipolar transistor induced by high power microwave is established in this paper. By analyzing the variations of device internal distributions of the electric field, the current density and the temperature with time, a detailed investigation of the damage effect and the mechanism of the bipolar transistor under the injection of 1GHz equivalent voltage signals from the base and collector is performed. The results show that temperature elevation occurs in the negative half-period and the maximum temperature falls slightly in the positive half-period when the signals are injected from the collector. Compared with the former, device damage occurs easily with the signals injected from the base. Specifically, the base-emitter junction is susceptible to damage. The damage results caused by two large-amplitude signals with initial phases of 0 and respectively indicate that the injected signal with an initial phase of is liable to cause device damage. Meanwhile, the emitter series resistance can enhance the capability of the device to withstand microwave damage effectively.

Keywords:

Authors and contacts

1.
School of Microelectronics, Xidian University, Key Lab of Ministry of Education for Wide Band-Gap Semiconductor Materials and Devices, Xi'an 710071, China
Funds: Project supported by the National Natural Science Foundation of China (Grant No. 60776034).

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Cited By

[1]	Backstrom M G, Lovstrand K G 2004 IEEE Trans. on Electromagn. Compat. 46 396
[2]	Brauer F, Sabath F, ter Haseborg J L 2009 IEEE International Symposium on Electromagnetic Compatibility, Austin, TX, USA, August 17–21, p237
[3]	Chahine I, Kadi M, Gaboriaud E, Louis A, Mazari B 2008 IEEE Trans. on Electromagn. Compat. 50 285
[4]	Wang H Y, Li J Y, Zhou Y H, Hu B, Yu X Y 2009 IEEE Trans. on Electromagn. Compat. 29 393
[5]	Hwang S M, Hong J I, Huh C S 2008 Prog. in Electromagn. Res. 81 61
[6]	Mansson D, Thottappillil R, Backstrom M, Lunden O 2008 IEEE Trans. on Electromagn. Compat. 50 101
[7]	Fan J P, Zhang L, Jia X Z 2010 High Power Laser Part. Beams 22 1319 (in Chinese) [范菊平, 张玲, 贾新章 2010 强激光与粒子束 textbf 22 1319]
[8]	Chai C C, Zhang B, Ren X R, Leng P 2010 J. Xidian Univ. 37 898 (in Chinese) [柴常春, 张冰, 任兴荣, 冷鹏 2010 西安电子科技大学学报 textbf 37 898]
[9]	Chai C C, Yang Y T, Zhang B Leng P, Yang Y, Rao W 2009 Semicond. Sci. Technol. 24 035003
[10]	Xi X W, Chai C C, Ren X R,Yang Y T, Zhang B, Hong X 2010 J. Semicond. 31 32
[11]	Xi X W, Chai C C, Ren X R,Yang Y T, Ma Z Y, Wang J 2010 J. Semicond. 31 49
[12]	Chai C C, Xi X W, Ren X R, Yang Y T, Ma Z Y 2010 Acta Phys. Sin. 59 8118 (in Chinese) [柴常春, 席晓文, 任兴荣, 杨银堂, 马振洋 2010 物理学报 textbf 59 8118]
[13]	Korte S, Camp M, Garbe H 2005 IEEE Trans. on Electromagn. Compat. 2 489
[14]	Yang Y C, Tan J C, Sheng D Y, Yang G 2008 High Power Laser Part. Beams 20 649 (in Chinese) [杨雨川, 谭吉春, 盛定仪, 杨耿 2008 强激光与粒子束 textbf 20 649]
[15]	Radasky W A 2010 Asia-Pacific Symposium on Electromagnetic Compatibility, Beijing, China, April 12–16, p758
[16]	Zhang B, Chai C C, Yang Y T 2010 Acta Phys. Sin. 50 8063 (in Chinese) [张冰, 柴常春, 杨银堂 2010 物理学报 50 8063]
[17]	Integrated Systems Engineering AG 2004 ISE-TCAD Dessis Simulation User's Manual Zurich, Switzerland, p142
[18]	Baliga B J, Ghandhi S K 1976 Solid-State Electron. 19 739
[19]	Liu S L, Zhang H C, Chai C C 2004 Physics Of Semiconductor Devices (Beijing: Publishing house of electronics industry) p27 [刘树林, 张华曹, 柴常春 2004 半导体器件物理 (北京: 电子工业出版社) 第27页]

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Vol. 61, Issue 7 - 2012-04-05

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