posted on 2024-05-29, 20:34authored byBhavnesh Jangid, Matthew R. Hermes, Laura Gagliardi
We investigated the use of density matrix embedding theory
to facilitate
the computation of core ionization energies (IPs) of large molecules
at the equation-of-motion coupled-cluster singles doubles with perturbative
triples (EOM-CCSD*) level in combination with the core–valence
separation (CVS) approximation. The unembedded IP-CVS-EOM-CCSD* method
with a triple-ζ basis set produced ionization energies within
1 eV of experiment with a standard deviation of ∼0.2 eV for
the core65 data set. The embedded variant contributed very little
systematic error relative to the unembedded method, with a mean unsigned
error of 0.07 eV and a standard deviation of ∼0.1 eV, in exchange
for accelerating the calculations by many orders of magnitude. By
employing embedded EOM-CC methods, we computed the core ionization
energies of the uracil hexamer, doped fullerene, and chlorophyll molecule,
utilizing up to ∼4000 basis functions within 1 eV from experimental
values. Such calculations are not currently possible with the unembedded
EOM-CC method.