Litcius/Paper detail

1200-V 4H-SiC Merged p-i-n Schottky Diodes With High Avalanche Capability

Li Liu, Jiupeng Wu, Na Ren, Qing Guo, Kuang Sheng

2020IEEE Transactions on Electron Devices28 citationsDOI

Abstract

In this article, the avalanche capability of the 1.2-kV 4H-SiC junction barrier Schottky (JBS) and merged p-i-n Schottky (MPS) diodes is investigated through simulation and experiments. For MPS diodes, the width of the wide P+ region (W) is found to have great effects on the device avalanche capability. MPS diodes with varied W-values (3-20 μm) and JBS diode are designed and fabricated, and their avalanche energy/current capability is tested with unclamped inductive switching tests. The experimental results show that the MPS diode has an optimized avalanche capability at W = 8-μm design. Simulation study reveals that the avalanche current is mainly distributed at the edges of the P+ regions in the JBS/MPS diodes as a result of the curvature-effect-induced electric field crowding. The localized current crowding and unbalanced current distribution in the avalanche mode contribute to a reduced effective power dissipation area and a weaker avalanche capability. The current nonuniformity coefficient (k) is used to characterize the severity of the current unbalance, and it is found that kdeclines as Wincreases when W = 3-8 μm and then gets increased when W exceeds 8 μm. Both the experimental and simulation results indicate that the MPS diode is superior to the JBS diode in avalanche capability, and the width of the wide P+ region in the MPS diode has an optimal design (8 μm in this article) which corresponds to the alleviated current crowding issue and 9%-19% improvement of the avalanche capability.

Topics & Concepts

Schottky diodeDiodeAvalanche diodeMaterials scienceOptoelectronicsCurrent crowdingAvalanche breakdownSingle-photon avalanche diodeSchottky barrierDissipationElectrical engineeringAvalanche photodiodeCurrent (fluid)Breakdown voltageVoltagePhysicsDetectorEngineeringThermodynamicsSilicon Carbide Semiconductor TechnologiesElectromagnetic Compatibility and Noise SuppressionSemiconductor materials and interfaces