A Physics-Based Model for a SiC JFET Device Accounting for the Mobility Dependence on Temperature and Electric Field

Author

Platania, E. ; Chen, Z. ; Chimento, F. ; Lu, L. ; Santi, E. ; Raciti, A. ; Hudgins, J. ; Mantooth, A. ; Sheridan, D. ; Cassady, J.

fYear

2008

fDate

5-9 Oct. 2008

Firstpage

1

Lastpage

8

Abstract

In this work a physical model for a SiC Junction Field Effect Transistor (JFET) is presented. The novel feature of the model is that the mobility dependence on both temperature and electric field is taken into account. This is particularly important for high-current power devices, where the maximum conduction current is limited by drift velocity saturation in the channel. The model equations are described in detail, emphasizing the differences introduced by the field-dependent mobility model. The model is then implemented in Pspice. Both static and dynamic simulation results are given. The results are validated with experimental results under static conditions and under resistive switching conditions.

Keywords

SPICE; junction gate field effect transistors; power semiconductor devices; silicon compounds; wide band gap semiconductors; JFET device; Pspice; SiC; drift velocity saturation; electric field; high-current power devices; junction field effect transistor; physics-based model; resistive switching; static conditions; temperature mobility dependence; Breakdown voltage; FETs; Fabrication; Industrial power systems; Photonic band gap; Power semiconductor devices; Semiconductor materials; Silicon carbide; Temperature dependence; Thermal conductivity;

fLanguage

English

Publisher

ieee

Conference_Titel

Industry Applications Society Annual Meeting, 2008. IAS '08. IEEE

Conference_Location

Edmonton, Alta.

ISSN

0197-2618

Print_ISBN

978-1-4244-2278-4

Electronic_ISBN

0197-2618

Type

conf

DOI

10.1109/08IAS.2008.364

Filename

4659152