A field-effect electron mobility model for SiC MOSFETs including high density of traps at the interface

Besides its favorable physical properties, high performant MOSFETs (metal-oxide–semiconductor field-effect transistors) fabrication in silicon carbide (SiC) remains an open issue due to their low channel mobility values. The effect of charge trapping and the scattering at interface states have been invoked as the main reasons for mobility reduction in SiC thermal oxidized MOS gated devices. In this paper, we propose a compact electron mobility model based on the well-established Lombardi mobility model to reproduce the mobility degradation commonly observed in these SiC devices. Using 2D electrical simulations along with the proposed model and taking into account interface traps Coulomb scattering, the experimental field-effect mobility of 4H-SiC MOSFET devices has been fitted with a good agreement.