A translationally equivariant and higher-order finite-difference method for Wannier interpolation yields more accurate Wannier centers, position matrices, electric polarization, orbital magnetization, and spin Hall conductivity.
Title resolution pending
2 Pith papers cite this work. Polarity classification is still indexing.
2
Pith papers citing it
verdicts
UNVERDICTED 2representative citing papers
Prediction of a quantized spin circular photogalvanic effect in altermagnetic Weyl semimetals, enabled by symmetry classification and confirmed in a tight-binding model and material candidate.
citing papers explorer
-
Accurate calculation of Wannier centers, position matrix, and composite operators using translationally equivariant and higher-order finite differences
A translationally equivariant and higher-order finite-difference method for Wannier interpolation yields more accurate Wannier centers, position matrices, electric polarization, orbital magnetization, and spin Hall conductivity.
-
Quantization of spin circular photogalvanic effect in altermagnetic Weyl semimetals
Prediction of a quantized spin circular photogalvanic effect in altermagnetic Weyl semimetals, enabled by symmetry classification and confirmed in a tight-binding model and material candidate.