Title :
Silicon carbide power MOSFET technology
Author :
Casady, J.B. ; Agarwal, A.K. ; Rowland, L.B. ; Seshadri, S. ; Siergiej, R.R. ; Sheridan, D.C. ; Mani, S. ; Sanger, P.A. ; Brandt, C.D.
Author_Institution :
Northrop Grumman Sci. & Technol. Center, Pittsburgh, PA, USA
Abstract :
4H-SiC UMOSFETs and DMOSFETs have been fabricated and tested with measured blocking voltages (1400 V and 900 V, respectively). Although these breakdown voltages were reasonable, obtaining sufficient channel mobility (50 cm2/Vs) to enable devices with practical current densities has thus far proven elusive owing to the poor quality of the SiC-SiO2 interface. DMOS structures suffer from a non-self aligned process, and gate oxide present over rough implanted and annealed SiC surfaces. Thus surface scattering effects and interface state density remain high, lowering carrier mobility. In addition, UMOS devices also suffer from poor inversion layer mobility due to the difficulties of forming high quality oxide on the sidewalls of the vertical trenches. In this paper we will explore these and other design and processing trade-offs
Keywords :
carrier mobility; interface states; inversion layers; power MOSFET; semiconductor device breakdown; semiconductor materials; silicon compounds; surface scattering; 1400 V; 4H-SiC; 900 V; DMOSFET; SiC-SiO2; UMOSFET; blocking voltage; breakdown voltage; carrier mobility; current density; gate oxide; interface state density; inversion layer; nonself aligned process; power MOSFET technology; rough surface; silicon carbide; surface scattering; vertical trench; Annealing; Current density; MOSFET circuits; Power MOSFET; Power measurement; Rough surfaces; Silicon carbide; Surface roughness; Testing; Voltage;
Conference_Titel :
Compound Semiconductors, 1997 IEEE International Symposium on
Conference_Location :
San Diego, CA
Print_ISBN :
0-7503-0556-8
DOI :
10.1109/ISCS.1998.711654
