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No Access Submitted: 02 March 2016 Accepted: 24 May 2016 Published Online: 08 June 2016

  • Temperature dependent simulation of diamond depleted Schottky PIN diodes

Journal of Applied Physics 119, 225703 (2016); https://doi.org/10.1063/1.4953385
Raghuraj Hathwar1, Maitreya Dutta1, Franz A. M. Koeck2, Robert J. Nemanich2, Srabanti Chowdhury1, and Stephen M. Goodnick1
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  • Raghuraj Hathwar
  • Maitreya Dutta
  • Franz A. M. Koeck
  • Robert J. Nemanich
  • Srabanti Chowdhury
  • Stephen M. Goodnick
ABSTRACT
Diamond is considered as an ideal material for high field and high power devices due to its high breakdown field, high lightly doped carrier mobility, and high thermal conductivity. The modeling and simulation of diamond devices are therefore important to predict the performances of diamond based devices. In this context, we use Silvaco® Atlas, a drift-diffusion based commercial software, to model diamond based power devices. The models used in Atlas were modified to account for both variable range and nearest neighbor hopping transport in the impurity bands associated with high activation energies for boron doped and phosphorus doped diamond. The models were fit to experimentally reported resistivity data over a wide range of doping concentrations and temperatures. We compare to recent data on depleted diamond Schottky PIN diodes demonstrating low turn-on voltages and high reverse breakdown voltages, which could be useful for high power rectifying applications due to the low turn-on voltage enabling high forward current densities. Three dimensional simulations of the depleted Schottky PIN diamond devices were performed and the results are verified with experimental data at different operating temperatures

ACKNOWLEDGMENTS

This research was supported by the ARPA-E SWITCHES Program under Grant No. “DE-AR0000453.”

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  1. © 2016 Author(s). Published by AIP Publishing.

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