DocumentCode
1373287
Title
Power SiC DMOSFET Model Accounting for Nonuniform Current Distribution in JFET Region
Author
Fu, Ruiyun ; Grekov, Alexander ; Hudgins, Jerry ; Mantooth, Alan ; Santi, Enrico
Author_Institution
Univ. of South Carolina, Columbia, SC, USA
Volume
48
Issue
1
fYear
2012
Firstpage
181
Lastpage
190
Abstract
The main goal of this paper is development of a new circuit-based silicon carbide (SiC) DMOSFET model which physically represents the mechanism of current saturation in power SiC DMOSFET. Finite-element simulations show that current saturation for a typical device geometry is due to 2-D carrier distribution effects in the JFET region caused by current spreading from the channel to the JFET region. For high drain-source voltages, most of the voltage drop occurs in the current spreading region located in the JFET region close to the channel. A new model is proposed that represents the nonuniform current distribution in the JFET region using a nonlinear voltage source and a resistance network. Advantages of the proposed model are that a single set of equations describes operation in both the linear and saturation regions, and that it provides a more physical description of MOSFET operation.
Keywords
electric potential; finite element analysis; junction gate field effect transistors; power MOSFET; semiconductor device models; silicon compounds; 2D carrier distribution effect; JFET region; SiC; circuit-based silicon carbide DMOSFET model; current saturation; device geometry; drain-source voltages; finite element simulation; nonlinear voltage source; nonuniform current distribution; power DMOSFET model; resistance network; voltage drop; Finite element methods; Integrated circuit modeling; JFETs; Logic gates; MOSFET circuits; Mathematical model; Silicon carbide; Current spreading region; DMOSFET; nonuniform current distribution; silicon carbide (SiC);
fLanguage
English
Journal_Title
Industry Applications, IEEE Transactions on
Publisher
ieee
ISSN
0093-9994
Type
jour
DOI
10.1109/TIA.2011.2175678
Filename
6075251
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