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Cation Vacancy in Wide Bandgap III‐Nitrides as Single‐Photon Emitter: A First‐Principles Investigation

Hang Zang, Xiaojuan Sun, Ke Jiang, Yang Chen, Shanli Zhang, Jianwei Ben, Yuping Jia, Tong Wu, Zhiming Shi, Dabing Li

2021Advanced Science14 citationsDOIOpen Access PDF

Abstract

Abstract Single‐photon sources based on solid‐state material are desirable in quantum technologies. However, suitable platforms for single‐photon emission are currently limited. Herein, a theoretical approach to design a single‐photon emitter based on defects in solid‐state material is proposed. Through group theory analysis and hybrid density functional theory calculation, the charge‐neutral cation vacancy in III‐V compounds is found to satisfy a unique 5‐electron‐8‐orbital electronic configuration with T d symmetry, which is possible for single‐photon emission. Furthermore, it is confirmed that this type of single‐photon emitter only exists in wide bandgap III‐nitrides among all the III‐V compounds. The corresponding photon energy in GaN, AlN, and AlGaN lies within the optimal range for transfer in optical fiber, thereby render the charge‐neutral cation vacancy in wide‐bandgap III‐nitrides as a promising single‐photon emitter for quantum information applications.

Topics & Concepts

PhotonCommon emitterBand gapNitrideDensity functional theoryVacancy defectMaterials scienceOptoelectronicsPhotonicsMolecular physicsAtomic physicsCondensed matter physicsPhysicsNanotechnologyOpticsQuantum mechanicsLayer (electronics)Diamond and Carbon-based Materials ResearchSemiconductor materials and devicesSemiconductor Quantum Structures and Devices