DocumentCode :
1069694
Title :
Trap and Inversion Layer Mobility Characterization Using Hall Effect in Silicon Carbide-Based MOSFETs With Gate Oxides Grown by Sodium Enhanced Oxidation
Author :
Tilak, Vinayak ; Matocha, Kevin ; Dunne, Greg ; Allerstam, Fredrik ; Sveinbjörnsson, Einar Ö
Author_Institution :
Semicond. Technol. Lab., GE Global Res., Niskayuna, NY, USA
Volume :
56
Issue :
2
fYear :
2009
Firstpage :
162
Lastpage :
169
Abstract :
Low-temperature MOS-gated Hall measurements and gated diode capacitance-voltage (C-V) measurements were performed to characterize both trap density and Hall mobility on 4H-silicon carbide MOSFETs with gate oxides grown by sodium enhanced oxidation (SEO) and thermally grown in N2O. The interface trap density Dit was determined close to the conduction band edge by Hall effect measurements to be 2?1013 cm-2 ? eV-1 in the N2O-based oxide sample and 1?1011 cm-2 ? eV-1 in the SEO sample. The presence of these interface trap states above the conduction band edge suggest that they are near interface oxide trap states rather than conventional fast interface trap states. The threshold voltage changes with temperature in MOSFETs with gate oxides grown thermally with N2O but not significantly in MOSFETs with gate oxides grown by SEO. The superior threshold voltage stability at low temperatures in the SEO-based MOSFET compared to the N2O oxidation-based MOSFET is due to lower trap density near the conduction band edge. Gated diode C-V measurements showed that MOSFETs with gate oxide grown by SEO had a higher density of interface traps (2.2?1012 cm-2) deeper in the bandgap compared to MOSFETs with gate oxides thermally grown in N2O (1.4?1012 cm-2). A maximum Hall mobility of 65 cm2/V ? s was measured in the SEO-based MOSFET, and 16 cm2/V ? s was measured on the N2O oxidation-based MOSFET at 225 K. The mobility correlates well with the interface trap density close to the conduction band edge as measured by Hall effect measurements but does not correlate with gated diode C-V measurements of traps deeper in the band gap. Temperature-dependent gated Hall mobility measurements were used to show that the inversion layer mobility in the SEO samples were limited by Coulomb scatterin- g from interface trapped charge and surface roughness scattering but not by phonon scattering.
Keywords :
Hall mobility; MOSFET; conduction bands; oxidation; silicon compounds; surface roughness; 4H-silicon carbide MOSFET; Coulomb scattering; Hall effect; Hall mobility; SiC; conduction band edge; gate oxide growth; gated diode capacitance-voltage measurement; interface oxide trap states; interface trapped charge; inversion layer mobility; low-temperature MOS-gated Hall measurements; silicon carbide-based MOSFET; sodium enhanced oxidation; surface roughness scattering; temperature 225 K; trap density; voltage stability; Capacitance measurement; Capacitance-voltage characteristics; Density measurement; Diodes; Hall effect; MOSFETs; Oxidation; Scattering; Silicon; Threshold voltage; Capacitance–voltage ($C$$V$); Hall effect; MOS devices; silicon carbide; sodium enhanced oxidation (SEO);
fLanguage :
English
Journal_Title :
Electron Devices, IEEE Transactions on
Publisher :
ieee
ISSN :
0018-9383
Type :
jour
DOI :
10.1109/TED.2008.2010601
Filename :
4752729
Link To Document :
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