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Space–Charge Profiles and Carrier Transport Properties in Dopant‐Free GaN‐Based p‐n Junction Formed by Distributed Polarization Doping

Takeru Kumabe, Seiya Kawasaki, Hirotaka Watanabe, Shugo Nitta, Yoshio Honda, Hiroshi Amano

2022physica status solidi (RRL) - Rapid Research Letters14 citationsDOI

Abstract

Herein, the operation of dopant‐free GaN‐based p‐n junctions formed by distributed polarization doping (DPD) is experimentally demonstrated and their space charge profiles and carrier transport properties are investigated. The device exhibits ideal space charge profiles explained by polarization effects and demonstrates the excellent controllability of DPD. In addition, it shows rectification and electroluminescence under forward‐biased conditions. The carrier transport properties could be explained by the conventional recombination/diffusion model used for impurity‐doped p‐n junctions. Repeatable breakdowns are also observed in all devices and the temperature‐dependent breakdown voltages reveal that the breakdowns are caused by avalanche multiplication, which is also the same as those reported in impurity‐doped GaN p‐n diodes. These results indicate that DPD is a promising doping technology for GaN‐based power devices overcoming any issues associated with conventional impurity doping.

Topics & Concepts

DopingMaterials scienceDopantOptoelectronicsImpuritySpace chargeRectificationDiodeCondensed matter physicsCharge carrierp–n junctionPolarization (electrochemistry)Depletion regionGallium nitrideWide-bandgap semiconductorSemiconductorVoltageNanotechnologyElectronChemistryElectrical engineeringPhysicsLayer (electronics)EngineeringPhysical chemistryOrganic chemistryQuantum mechanicsGaN-based semiconductor devices and materialsSemiconductor Quantum Structures and DevicesSemiconductor materials and interfaces
Space–Charge Profiles and Carrier Transport Properties in Dopant‐Free GaN‐Based p‐n Junction Formed by Distributed Polarization Doping | Litcius