Accuracy of TDDFT for spin-polarized systems
Posted: Thu Jun 09, 2022 11:32 am
Dear All,
According to the VASP wiki page about BSE type calculations (https://www.vasp.at/wiki/index.php/Beth ... lculations):
I tried answering this by calculating the optical absorption spectrum of ZnO with and without spin polarization, but the results were identical. I imagine that the case may be different for systems that naturally polarize their spin (e.g. antiferromagnetic systems) but since such systems cannot be described without spin polarization, it is hard to test.
I appreciate any insights about this,
Sincerely,
Guy
According to the VASP wiki page about BSE type calculations (https://www.vasp.at/wiki/index.php/Beth ... lculations):
I wonder if there is a more quantitative estimation of how less accurate TDHF calculations for spin-polarized systems are. Say, if I look at a certain peak in the imaginary part of the dielectric function at some energy, what will be the uncertainty in peak position (in eV), assuming that all parameters of the calculation are highly converged?THDF/BSE calculations can be performed for non-spin-polarized, spin-polarized, and noncollinear cases, as well as the case with spin-orbit coupling. There is, however, one caveat. The local exchange-correlation kernel is approximated by the density-density part only. This makes predictions for spin-polarized systems less accurate than for non-spin-polarized systems.
I tried answering this by calculating the optical absorption spectrum of ZnO with and without spin polarization, but the results were identical. I imagine that the case may be different for systems that naturally polarize their spin (e.g. antiferromagnetic systems) but since such systems cannot be described without spin polarization, it is hard to test.
I appreciate any insights about this,
Sincerely,
Guy