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Characterization and analysis of low-temperature time-to-failure behavior in forward-biased Schottky-type <i>p</i>-GaN gate HEMTs

Jiabei He, Jin Wei, Yang Li, Zheyang Zheng, Song Yang, Baoling Huang, Kevin J. Chen

2020Applied Physics Letters41 citationsDOI

Abstract

The low-temperature gate reliability of Schottky-type p-GaN gate AlGaN/GaN heterojunction field-effect transistors under forward gate voltage stress is investigated. Both temperature-accelerated and voltage-accelerated time-dependent gate breakdown stress experiments are performed. The p-GaN gate exhibits a shorter time-to-failure at a lower temperature. It is found that the time-to-failure at “use conditions” predicted by acceleration tests at high gate bias stress could be overestimated at low temperatures. Such a discrepancy stems from the distinct dominant gate leakage mechanisms at high/low gate bias stress conditions. The dominant physical mechanism of the low-temperature gate leakage current is identified to be Poole–Frenkel emission at low gate bias and Fowler–Nordheim tunneling at high bias. From the physical model, a more accurate lifetime projection can be obtained for given use conditions.

Topics & Concepts

Materials scienceOptoelectronicsLeakage (economics)Quantum tunnellingSchottky diodeTime-dependent gate oxide breakdownStress (linguistics)Schottky barrierTransistorGate oxideVoltageElectrical engineeringDiodeLinguisticsEngineeringPhilosophyMacroeconomicsEconomicsGaN-based semiconductor devices and materialsSemiconductor materials and devicesAdvancements in Semiconductor Devices and Circuit Design