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RESEARCH PRODUCT
The VN2 negatively charged defect in diamond. A quantum mechanical investigation of the EPR response
Anna Maria FerrariBernard KirtmanFrancesco Silvio GentileAlexander PlatonenkoRoberto DovesiGiulio Di Palmasubject
Electronic structuredefectMaterials scienceVNPhonon2002 engineering and technologyElectronic structureengineering.materialBand structure; Comparison simulation-experiment; Diamond; Electron paramagnetic resonance response; Electronic structure; IR spectrum; VN; 2; 0; defect; VN; 2; −; defect010402 general chemistry01 natural sciencesMolecular physicslaw.inventionlawSpin waveVacancy defectGeneral Materials ScienceIR spectrumElectron paramagnetic resonanceHyperfine structure−DiamondBand structureGeneral ChemistryComparison simulation-experiment021001 nanoscience & nanotechnology0104 chemical sciencesengineeringDiamond0210 nano-technologyGround stateElectron paramagnetic resonance responsedescription
Abstract The VN 2 − defect in diamond consists of a vacancy surrounded by two substitutional nitrogen atoms, which lower the local symmetry from Td to C2v. Calculations of the doublet ground state geometry, electronic structure, EPR parameters, and IR spectra of this defect are reported along with a preliminary investigation of the observed optical transition. For the most part our results were obtained using a uniform charge compensated supercell approach together with the B3LYP functional and all-electron Gaussian basis sets designed for the properties studied. In particular, the computed hyperfine and quadrupolar EPR parameters for the carbon and nitrogen atoms adjacent to the vacancy agree very well with the experiments (Fermi contact values are 245 MHz vs 241 for 13C, and 4.1 vs 4.0 for 15N). The accompanying spin distribution may be described as a damped spherical spin wave with little spin density on the nitrogen atoms. IR spectra show some interesting features in the range of approximately 360–1310 cm−1, which are absent in the pristine diamond. Functionals without exact exchange, such as PBE, better reproduce the observed zero phonon line.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2020-04-01 | Carbon |