Perturbation Theory Treatment of Spin–Orbit Coupling. III: Coupled Perturbed Method for Solids

Abstract: A previously proposed noncanonical coupled-perturbed Kohn−Sham density functional theory (KS-DFT)/Hartree− Fock (HF) treatment for spin−orbit coupling is here generalized to infinite periodic systems. The scalar-relativistic periodic KS-DFT/ HF solution, obtained with a relativistic effective core potential, is taken as the zeroth-order approximation. Explicit expressions are given for the total energy through third-order, which satisfy the 2N + 1 rule (i.e., requiring only the first-order perturbed wave funct… Show more

“…Crystalline orbitals are expressed as linear combinations of atomic orbitals . We use the ECP60MDF and ECP28MDF effective-core potentials by Dolg and co-workers, for W and Se, respectively, derived from multiconfigurational four-component Dirac–Coulomb–Breit calculations. , The valence basis sets are those from ref . We use the PBE generalized-gradient approximation, GGA, xc functional (plain and hybridized with a fraction α of exact Fock exchange), as well as the r 2 SCAN meta-generalized-gradient, meta-GGA, xc functional, − in its original (SU(2) gauge-dependent) version and in its (SU(2) gauge-invariant), current-dependent version J-r 2 SCAN .…”

“…We use the PBE generalized-gradient approximation, GGA, xc functional (plain and hybridized with a fraction α of exact Fock exchange), as well as the r 2 SCAN meta-generalized-gradient, meta-GGA, xc functional, − in its original (SU(2) gauge-dependent) version and in its (SU(2) gauge-invariant), current-dependent version J-r 2 SCAN . SOC integrals are computed analytically for both the energy and forces, and SOC is treated self-consistently. ,,,− …”

“…In conclusion, we stress that the key to these SCDFT results is the possibility to account for SOC self-consistently while employing energy functionals and effective potentials that depend (implicitly or explicitly) on spin currents. Indeed, it is this dependence on J⃗ that unlocks a full SOC-induced orbital relaxation. , Without spin currents in the xc potential, any SOC-including calculation with a (semi)­local DFA reduces to a second-variational post-self-consistent approach, for all practical purposes. Figure C further shows this by comparing, on the same scale, the spin current J z in the xy plane close to a Se atom computed without (top) and with (bottom) inclusion of J⃗ in the xc potential.…”

Unveiling the Role of Spin Currents on the Giant Rashba Splitting in Single-Layer WSe₂

“…Crystalline orbitals are expressed as linear combinations of atomic orbitals . We use the ECP60MDF and ECP28MDF effective-core potentials by Dolg and co-workers, for W and Se, respectively, derived from multiconfigurational four-component Dirac–Coulomb–Breit calculations. , The valence basis sets are those from ref . We use the PBE generalized-gradient approximation, GGA, xc functional (plain and hybridized with a fraction α of exact Fock exchange), as well as the r 2 SCAN meta-generalized-gradient, meta-GGA, xc functional, − in its original (SU(2) gauge-dependent) version and in its (SU(2) gauge-invariant), current-dependent version J-r 2 SCAN .…”

“…We use the PBE generalized-gradient approximation, GGA, xc functional (plain and hybridized with a fraction α of exact Fock exchange), as well as the r 2 SCAN meta-generalized-gradient, meta-GGA, xc functional, − in its original (SU(2) gauge-dependent) version and in its (SU(2) gauge-invariant), current-dependent version J-r 2 SCAN . SOC integrals are computed analytically for both the energy and forces, and SOC is treated self-consistently. ,,,− …”

“…In conclusion, we stress that the key to these SCDFT results is the possibility to account for SOC self-consistently while employing energy functionals and effective potentials that depend (implicitly or explicitly) on spin currents. Indeed, it is this dependence on J⃗ that unlocks a full SOC-induced orbital relaxation. , Without spin currents in the xc potential, any SOC-including calculation with a (semi)­local DFA reduces to a second-variational post-self-consistent approach, for all practical purposes. Figure C further shows this by comparing, on the same scale, the spin current J z in the xy plane close to a Se atom computed without (top) and with (bottom) inclusion of J⃗ in the xc potential.…”

Unveiling the Role of Spin Currents on the Giant Rashba Splitting in Single-Layer WSe₂

The Electron‐Density Distribution of UCl₄ and Its Topology from X‐ray Diffraction

The Electron‐Density Distribution of UCl₄ and Its Topology from X‐ray Diffraction