Analysis of high field effects on the steady-state current-voltage response of semi-insulating 4H-SiC for photoconductive switch applications

Date

2015

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Volume Title

Publisher

AIP

Abstract

A model-based analysis of the steady-state, current-voltage response of semi-insulating 4H-SiC is carried out to probe the internal mechanisms, focusing on electric field driven effects. Relevant physical processes, such as multiple defects, repulsive potential barriers to electron trapping, band-to-trap impact ionization, and field-dependent detrapping, are comprehensively included. Results of our model match the available experimental data fairly well over orders of magnitude variation in the current density. A number of important parameters are also extracted in the process through comparisons with available data. Finally, based on our analysis, the possible presence of holes in the samples can be discounted up to applied fields as high as ∼275 kV/cm.

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Keywords

Ionization Processes, Electronic Transport, Electrical Properties and Parameters, Potential Energy Barrier, Ohmic Contacts, Electron Traps, Phonons, Electronic Band Structure, Transport Properties, Photoconductive Switch

Citation

R. Tiskumara, R.P. Joshi, D. Mauch, J.C. Dickens, and A.A. Neuber “Analysis of high field effects on the steady-state current-voltage response of semi-insulating 4H-SiC for photoconductive switch applications,” Journal of Applied Physics 118, 094701 (2015) https://doi.org/10.1063/1.4929809

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