Micromachines (Apr 2021)

Understanding the Leakage Mechanisms and Breakdown Limits of Vertical GaN-on-Si p<sup>+</sup>n<sup>−</sup>n Diodes: The Road to Reliable Vertical MOSFETs

  • Kalparupa Mukherjee,
  • Carlo De Santi,
  • Matteo Buffolo,
  • Matteo Borga,
  • Shuzhen You,
  • Karen Geens,
  • Benoit Bakeroot,
  • Stefaan Decoutere,
  • Andrea Gerosa,
  • Gaudenzio Meneghesso,
  • Enrico Zanoni,
  • Matteo Meneghini

DOI
https://doi.org/10.3390/mi12040445
Journal volume & issue
Vol. 12, no. 4
p. 445

Abstract

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This work investigates p+n−n GaN-on-Si vertical structures, through dedicated measurements and TCAD simulations, with the ultimate goal of identifying possible strategies for leakage and breakdown optimization. First, the dominant leakage processes were identified through temperature-dependent current–voltage characterization. Second, the breakdown voltage of the diodes was modelled through TCAD simulations based on the incomplete ionization of Mg in the p+ GaN layer. Finally, the developed simulation model was utilized to estimate the impact of varying the p-doping concentration on the design of breakdown voltage; while high p-doped structures are limited by the critical electric field at the interface, low p-doping designs need to contend with possible depletion of the entire p-GaN region and the consequent punch-through. A trade-off on the value of p-doping therefore exists to optimize the breakdown.

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