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Bandgap Engineering and Oxygen Vacancy Defect Electroactivity Inhibition in Highly Crystalline N-Alloyed Ga<sub>2</sub>O<sub>3</sub> Films through Plasma-Enhanced Technology

Huaile He, Chao Wu, Haizheng Hu, Shunli Wang, Fabi Zhang, Daoyou Guo, Fengmin Wu

2023The Journal of Physical Chemistry Letters103 citationsDOI

Abstract

Previous research has shown that the hybridization of N 2p and O 2p orbitals effectively suppresses the electrical activity of oxygen vacancies in oxide semiconductors. However, achieving N-alloyed Ga 2 O 3 films, known as GaON, poses a significant challenge due to nitrogen’s limited solubility in the material. In this study, a new method utilizing plasma-enhanced chemical vapor deposition with high-energy nitrogen plasma was explored to enhance the nitrogen solubility in the material. By adjusting the N 2 and O 2 carrier gas ratio, we could tune the thin film’s bandgap from 4.64 to 3.25 eV, leading to a reduction in the oxygen vacancy density from 32.89% to 19.87%. GaON-based photodetectors exhibited superior performance compared to that of Ga 2 O 3 -based devices, with a lower dark current and a faster photoresponse speed. This investigation presents an innovative approach to achieving high-performance devices based on Ga 2 O 3 .

Topics & Concepts

Materials scienceBand gapSolubilityNitrogenVacancy defectOxygenChemical vapor depositionPlasmaOxideOptoelectronicsThin filmSemiconductorAnalytical Chemistry (journal)Chemical engineeringNanotechnologyPhysical chemistryChemistryCrystallographyMetallurgyOrganic chemistryPhysicsEngineeringQuantum mechanicsGa2O3 and related materialsZnO doping and propertiesAdvanced Photocatalysis Techniques
Bandgap Engineering and Oxygen Vacancy Defect Electroactivity Inhibition in Highly Crystalline N-Alloyed Ga<sub>2</sub>O<sub>3</sub> Films through Plasma-Enhanced Technology | Litcius