Microscopic identification and electronic structure of a di-hydrogen–vacancy complex in silicon by optical detection of magnetic resonance

18 June 1990

journal article
research article
Published by American Physical Society (APS) in Physical Review Letters

Vol. 64 (25) , 3042-3045
https://doi.org/10.1103/physrevlett.64.3042

Abstract

We present a microscopic identification of a hydrogen-related-complex defect in electron-irradiated, hydrogenated, boron-doped, single-crystalline silicon, by optical detection of magnetic resonance. The symmetry of this defect has been deduced as

C_{2 v}

, and from the observed hyperfine interactions the defect is identified as a di-hydrogen–vacancy complex, where the H atoms passivate two of the four dangling bonds in a monovacancy. A spin-triplet is the lowest electronic excited state of the defect, which exhibits a strong recombination channel for the free-carriers.

Keywords

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