1600 V, 5.1 mΩ.cm2 4H-SiC BJT with a High Current Gain of β=70

被引：12

作者：

Zhang, Jianhui ^{[1
]}

Alexandrov, Petre ^{[1
]}

Zhao, Jian H. ^{[2
]}

机构：

[1] United Silicon Carbide Inc, 100 Jersey Ave,Bldg A, New Brunswick, NJ 08901 USA

[2] Rutgers State Univ, ECE Dept, SiCLAB, Piscataway, NJ 08854 USA

来源：

SILICON CARBIDE AND RELATED MATERIALS 2007, PTS 1 AND 2 | 2009年 / 600-603卷

关键词：

silicon carbide; bipolar junction transistor; power transistor; BIPOLAR JUNCTION TRANSISTORS;

D O I：

10.4028/www.scientific.net/MSF.600-603.1155

中图分类号：

TQ174 [陶瓷工业]; TB3 [工程材料学];

学科分类号：

0805 ; 080502 ;

摘要：

This paper reports a newly achieved best result on the common emitter current gain of 4H-SiC high power bipolar junction transistors (BJTs). A fabricated 1600 V - 15 A 4H-SiC power BJT with an active area of 1.7 mm(2) shows a high DC current gain (beta) of 70, when it conducts 9.8 A collector current at a base current of only 140 mA. The maximum AC current gain (Delta I-C/Delta I-B) is up to 78. This high performance BJT has an open base collector-to-emitter blocking voltage (V-CEO) of over 1674 V with a leakage current of 1.6 mu A and a specific on-resistance (RSP-ON) of 5.1 m Omega.cm(2) when it conducts 7.0 A (412 A/cm(2)) at a forward voltage drop of V-CE = 2.1 V. A large area 4H-SiC BJT with a footprint of 4.1 mm x 4.1 mm has also shown a DC current gain over 50. These high-gain, high-voltage and high-current 4H-SiC BJTs further support a promising future for 4H-SiC BJT applications.

引用

页码：1155 / +

页数：2

共 50 条

[31] 5.0 kV 4H-SiC SEMOSFET with low RonS of 88 m Ω cm2
Sugawara, Y
Asano, K
Takayama, D
Ryu, S
Singh, R
Palmour, J
Hayashi, T
SILICON CARBIDE AND RELATED MATERIALS 2001, PTS 1 AND 2, PROCEEDINGS, 2002, 389-3 : 1199 - 1202
[32] 4,308V, 20.9 mΩ•cm2 4H-SiC MPS diodes based on a 30μm drift layer
Wu, J
Fursin, L
Li, Y
Alexandrov, P
Zhao, JH
SILICON CARBIDE AND RELATED MATERIALS 2003, PRTS 1 AND 2, 2004, 457-460 : 1109 - 1112
[33] 4,308V, 20.9 mΩ-cm2 4H-SiC MPS diodes based on a 30μm drift layer
Wu, J.
Fursin, L.
Li, Y.
Alexandrov, P.
Zhao, J.H.
Mater Sci Forum, 1600, II (1109-1112):
[34] High-Temperature Operation of 50 A (1600 A/cm2), 600 V 4H-SiC Vertical-Channel JFETs for High-Power Applications
Cheng, L.
Sankin, I.
Bondarenko, V.
Mazzola, M. S.
Scofield, J. D.
Sheridan, D. C.
Martin, P.
Casady, J. R. B.
Casady, J. B.
SILICON CARBIDE AND RELATED MATERIALS 2007, PTS 1 AND 2, 2009, 600-603 : 1055 - +
[35] The Optimised Design and Characterization of 1200 V/2.0 mΩ cm2 4H-SiC V-groove Trench MOSFETs
Uchida, Kosuke
Saitoh, Yu
Hiyoshi, Tom
Masuda, Takeyoshi
Wada, Keiji
Tamaso, Hideto
Hatayama, Tomoaki
Hiratsuka, Kenji
Tsuno, Takashi
Furumai, Masaki
Mikamura, Yasuki
2015 IEEE 27TH INTERNATIONAL SYMPOSIUM ON POWER SEMICONDUCTOR DEVICES & IC'S (ISPSD), 2015, : 85 - 88
[36] Fabrication of 2700-v 12-mΩ•cm2 non ion-implanted 4H-SiC BJTs with common-emitter current gain of 50
Ghandi, Reza
Lee, Hyung-Seok
Domeij, Martin
Buono, Benedetto
Zetterling, Carl-Mikael
Ostling, Mikael
IEEE ELECTRON DEVICE LETTERS, 2008, 29 (10) : 1135 - 1137
[37] Comments on "1.88-mΩ . cm2 1650-V Normally on 4H-SiC TI-VJFET"
Veliadis, V.
IEEE TRANSACTIONS ON ELECTRON DEVICES, 2010, 57 (12) : 3540 - 3543
[38] Novel 4H-SiC BJT utilizing floating buried layer in base for high current gain, high current gain stability and high breakdown voltage
Zhang, Yourun
Zhang, Bo
Li, Zhaoji
Deng, Xiaochuan
Liu, Xilin
COMPEL-THE INTERNATIONAL JOURNAL FOR COMPUTATION AND MATHEMATICS IN ELECTRICAL AND ELECTRONIC ENGINEERING, 2010, 29 (02) : 515 - 521
[39] 14.6 mΩcm2 3.4 kV DIMOSFET on 4H-SiC (000-1)
Kono, Hiroshi
Furukawa, Masaru
Ariyoshi, Keiko
Suzuki, Takuma
Tanaka, Yasunori
Shinohe, Takashi
SILICON CARBIDE AND RELATED MATERIALS 2013, PTS 1 AND 2, 2014, 778-780 : 935 - 938
[40] 10-kV 123-mΩ.cm2 4h-sic Power DMOSFETS
Ryu, SH
Krishnaswami, S
O'Loughlin, M
Richmond, J
Agarwal, A
Palmour, J
Hefner, AR
IEEE ELECTRON DEVICE LETTERS, 2004, 25 (08) : 556 - 558

← 1 2 3 4 5 →