Litcius/Paper detail

GaN-on-GaN p-i-n diodes with avalanche capability enabled by eliminating surface leakage with hydrogen plasma treatment

Kai Fu, Ziyi He, Chen Yang, Jingan Zhou, Houqiang Fu, Yuji Zhao

2022Applied Physics Letters19 citationsDOIOpen Access PDF

Abstract

Traditional mesa terminations require precise angle design to reduce the electric field at the edge and surface treatment to reduce etch damage. Otherwise, the device usually suffers a premature breakdown. This work proposes the use of easy-to-implement hydrogen plasma treatment to solve the premature breakdown caused by mesa and demonstrates the avalanche capability in GaN-on-GaN p-i-n diodes. The breakdown electric field when the avalanche occurred was ∼2.3 MV/cm at room temperature for a GaN drift layer with a doping concentration of ∼7 × 1015 cm−3, which is consistent with the theoretical value. The temperature coefficient of the avalanche breakdown voltage of the devices was 4.64–4.85 × 10−4 K−1. This work shows a simple and effective approach to achieve avalanche capability in vertical GaN power devices, which can serve as an important reference for the future development of efficient and robust GaN power electronics.

Topics & Concepts

Materials scienceBreakdown voltageOptoelectronicsAvalanche breakdownAvalanche diodeElectric fieldDiodeWide-bandgap semiconductorPlasmaDopingLeakage (economics)Gallium nitrideVoltageLayer (electronics)Electrical engineeringNanotechnologyMacroeconomicsEconomicsEngineeringPhysicsQuantum mechanicsGaN-based semiconductor devices and materialsGa2O3 and related materialsSilicon Carbide Semiconductor Technologies