Temel Kavramlar
Density functional approximations (DFAs) and self-interaction corrected DFAs exhibit varying performance in describing the ionization energies of 3d transition metal atoms, with the self-interaction correction introducing an "energy penalty" for the noded 3d orbitals.
Özet
The study investigates the performance of various density functional approximations (DFAs) and self-interaction corrected DFAs in describing the ionization energies of 3d transition metal atoms (Sc-Zn).
Key findings:
- Standard DFAs (LSDA, PBE, r2SCAN) tend to overbind the 4s electron in the 4s^1 configuration and underbind the first 4s electron in the 4s^2 configuration, leading to errors in the first ionization energies.
- The self-interaction corrected DFAs (FLOSIC-DFT) suffer from a self-interaction correction (SIC) energy penalty for the noded 3d orbitals, leading to an underestimation of the number of 4s electrons in some cases.
- The ground-state measure of the sd transfer error decreases from 0.65 eV in LSDA to 0.44 eV in PBE to 0.09 eV in r2SCAN, indicating improved performance in balancing the description of s and d electrons.
- The SIC energy penalty is largest when removing the first 3d electron from a 3d^5 or 3d^10 configuration, leading to severe underestimation of the corresponding ionization energies in FLOSIC-DFT.
- Locally scaling the self-interaction correction (LSIC-LSDA) can effectively cancel out the s and d errors, providing accurate ionization energies.
İstatistikler
The mean errors (ME) and mean absolute errors (MAE) for the first, second, and third ionization energies of the 3d transition metal atoms are reported.
Alıntılar
"While, from total energy differences, we see that the standard DFAs (LSDA, PBE, and r2SCAN) overbind the 4s electron in the 4s^1 configuration, and underbind the first 4s electron in the 4s^2 configuration, the self-interaction corrected DFAs suffer from a SIC energy penalty for noded d electrons."
"The SIC energy penalty appears largest when an electron is removed from either a half-filled (3d^5) or completely-filled (3d^10) subshell, as evidenced by a severe underestimation of the ionization energy in these cases."