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Frozen-Density Embedding Theory based simulations with experimental electron densities

Chemical Physics 2020-06-22 v2

Abstract

The basic idea of Frozen-Density Embedding Theory (FDET) is the constrained minimisation of the Hohenberg-Kohn density functional EHK[ρ]E^{HK}[\rho] performed using the auxiliary functional EvABFDET[ΨA,ρB]E_{v_{AB}}^{FDET}[\Psi_A,\rho_B], where ΨA\Psi_A is the embedded NAN_A-electron wave-function and ρB(r)\rho_B(\vec{\mathrm{r}}) a non-negative function in real space integrating to a given number of electrons NBN_B. This choice of independent variables in the total energy functional EvABFDET[ΨA,ρB]E_{v_{AB}}^{FDET}[\Psi_A,\rho_B] makes it possible to treat the corresponding two components of the total density using different methods in multi-level simulations. We demonstrate, for the first time, the applications of FDET using ρB(r)\rho_B(\vec{\mathrm{r}}) reconstructed from X-ray diffraction data on a molecular crystal. For eight hydrogen-bonded clusters involving a chromophore (represented with ΨA\Psi_A) and the glycylglycine molecule (represented as ρB(r)\rho_B(\vec{\mathrm{r}})), FDET is used to derive excitation energies. It is shown that experimental densities are suitable to be used as ρB(r)\rho_B(\vec{\mathrm{r}}) in FDET based simulations.

Keywords

Cite

@article{arxiv.2005.13409,
  title  = {Frozen-Density Embedding Theory based simulations with experimental electron densities},
  author = {Niccolò Ricardi and Michelle Ernst and Piero Macchi and Tomasz A. Wesolowski},
  journal= {arXiv preprint arXiv:2005.13409},
  year   = {2020}
}

Comments

18 pages, 5 figures

R2 v1 2026-06-23T15:51:19.893Z