Advanced Electronic Structure Methods (5 sub-skills: gw-approximation, hubbard-u, spin-orbit-coupling, topological-invariants, van-der-waals)
Beyond-standard-DFT methods for accurate electronic properties in materials where standard GGA/LDA fails qualitatively. These methods address strong correlation, spin-orbit physics, topological classification, quasiparticle energies, and long-range dispersion interactions.
| Sub-Skill | Directory | Use Case | Key QE / VASP Keywords |
|---|---|---|---|
| DFT+U (Hubbard U) | hubbard-u/ | Strongly correlated d/f-electron systems, Mott insulators, transition metal oxides | lda_plus_u, Hubbard_U(i), HUBBARD card, hp.x; VASP: LDAU, LDAUU |
| Spin-Orbit Coupling | spin-orbit-coupling/ | Heavy elements, topological insulators, Rashba splitting, magnetic anisotropy, band inversion | noncolin, lspinorb, FR pseudopotentials; VASP: , |
LSORBITLNONCOLLINEAR| Topological Invariants | topological-invariants/ | Z2 classification, Wilson loops, Berry phase, Wannier charge centers, topological insulator screening | z2pack, pw2wannier90.x, Wannier90; parity eigenvalues at TRIM |
| GW Approximation | gw-approximation/ | Accurate quasiparticle band gaps, band alignment, comparison with photoemission | Yambo / SternheimerGW interface for QE; VASP: ALGO=GW0, ALGO=scGW |
| Van der Waals Corrections | van-der-waals/ | Layered materials, molecular crystals, adsorption, MOFs | vdw_corr='dft-d3', input_dft='rvv10'; VASP: IVDW, LUSE_VDW |
Does your system have open d or f shells (TM oxides, lanthanides, actinides)?
YES --> DFT+U (hubbard-u/)
NO --> Standard DFT may suffice for ground-state energetics
Does your system contain heavy elements (Z > 50) or involve spin-dependent phenomena?
YES --> Spin-Orbit Coupling (spin-orbit-coupling/)
NO --> Scalar-relativistic pseudopotentials are sufficient
Do you need to classify topological order (Z2, Chern number, surface states)?
YES --> Topological Invariants (topological-invariants/)
NO --> Standard band structure is sufficient
Do you need accurate band gaps (comparison with photoemission/optical data)?
YES --> GW Approximation (gw-approximation/)
NO --> DFT gaps with scissors correction may suffice
Are van der Waals interactions important (layered, molecular, adsorption)?
YES --> Van der Waals Corrections (van-der-waals/)
NO --> Standard DFT is fine
These methods are NOT mutually exclusive. Common combinations include:
| Material Class | Recommended Method(s) | Example Systems |
|---|---|---|
| Transition metal oxides | DFT+U | NiO, Fe2O3, LiFePO4, SrTiO3 |
| f-electron compounds | DFT+U (large U) | CeO2, UO2, SmB6 |
| Topological insulators | SOC + topological invariants | Bi2Se3, Bi2Te3, HgTe |
| Rashba systems | SOC | BiTeI, GeTe, oxide interfaces |
| Semiconductors (accurate gaps) | GW | Si, GaAs, ZnO, MgO |
| Layered materials | vdW corrections | graphite, MoS2, h-BN, black P |
| Molecular crystals | vdW corrections | organic semiconductors, ice |
| Correlated topological | DFT+U + SOC + Z2 | SmB6, pyrochlore iridates |
| 2D magnets | DFT+U + vdW + SOC | CrI3, Fe3GeTe2 |
pw.x, pp.x, hp.x, projwfc.x, bands.x)_rel or ONCVPSP _FR)pymatgen, ASE, numpy, scipy, matplotlib, z2pack