<p>Accurate EPR <i>g</i>-tensors of point defects in solids often require supercells containing hundreds to thousands of atoms to suppress defect–image interactions. In this regime, perturbative linear-response implementations can become impractical because the induced-current response is highly sensitive to Brillouin-zone sampling, typically demanding dense <i>k</i>-point meshes. Here we implement a <i>single-point</i> formulation of the converse orbital-magnetization approach for EPR <i>g</i>-tensor calculations in periodic systems. Relative to converse schemes based on covariant finite-difference <i>k</i>-derivatives, the present formulation removes the auxiliary diagonalizations at <b>k</b> ± <b>q</b> and avoids explicit <i>k</i>-space summations, improving both computational efficiency and numerical stability under <i>Γ</i>-only sampling. We validate the implementation through a benchmark set of charged and neutral defects in Si, diamond, and <i>α</i>-quartz, comparing against (i) the covariant converse method and (ii) linear-response calculations in QE-GIPAW and CASTEP. Using the absolute relative deviation of the principal <i>g</i>-tensor components from experiment as a metric, we find that the single-point scheme consistently delivers smooth, accelerated supercell-size convergence and remains stable in challenging cases with partially delocalized spin densities, where the covariant finite-difference approach can exhibit non-monotonic trends (notably for V<sup>+</sup> in Si). Overall, the single-point converse formulation provides a practical accuracy-per-cost advantage for large-scale defect EPR modeling.</p>

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Accelerating convergence in orbital magnetization calculations through a single point formula and applications to defect EPR g-tensor fingerprints

  • S. Fioccola,
  • L. Giacomazzi,
  • D. Ceresoli,
  • N. Richard,
  • L. Martin-Samos,
  • A. Hemeryck

摘要

Accurate EPR g-tensors of point defects in solids often require supercells containing hundreds to thousands of atoms to suppress defect–image interactions. In this regime, perturbative linear-response implementations can become impractical because the induced-current response is highly sensitive to Brillouin-zone sampling, typically demanding dense k-point meshes. Here we implement a single-point formulation of the converse orbital-magnetization approach for EPR g-tensor calculations in periodic systems. Relative to converse schemes based on covariant finite-difference k-derivatives, the present formulation removes the auxiliary diagonalizations at k ± q and avoids explicit k-space summations, improving both computational efficiency and numerical stability under Γ-only sampling. We validate the implementation through a benchmark set of charged and neutral defects in Si, diamond, and α-quartz, comparing against (i) the covariant converse method and (ii) linear-response calculations in QE-GIPAW and CASTEP. Using the absolute relative deviation of the principal g-tensor components from experiment as a metric, we find that the single-point scheme consistently delivers smooth, accelerated supercell-size convergence and remains stable in challenging cases with partially delocalized spin densities, where the covariant finite-difference approach can exhibit non-monotonic trends (notably for V+ in Si). Overall, the single-point converse formulation provides a practical accuracy-per-cost advantage for large-scale defect EPR modeling.