posted on 2018-10-22, 00:00authored byFrédéric Labat, Bartolomeo Civalleri, Roberto Dovesi
We present the implementation of
an implicit solvation model in
the CRYSTAL code. The solvation energy is separated into two components:
the electrostatic contribution arising from a self-consistent reaction
field treatment obtained within a generalized finite-difference Poisson
model, augmented by a nonelectrostatic contribution proportional to
the solvent-accessible surface area of the solute. A discontinuous
dielectric boundary is used, along with a solvent-excluded surface
built from interlocking atom-centered spheres on which apparent surface
point charges are mapped. The procedure is general and can be performed
at both the Hartree–Fock and density functional theory levels,
with pure or hybrid functionals, for systems periodic in 0, 1, and
2 directions, that is, for isolated molecules and extended polymers
and surfaces. The Poisson equation resolution and apparent surface
charge formalism is first validated on model analytical test cases.
The good agreement obtained on solvation free energies is further
confirmed by calculations performed on a large test set of 501 neutral
molecules, for which a mean unsigned error of 1.3 kcal/mol is obtained
when compared to the available experimental data. Importantly, the
self-consistent reaction field procedure converges well for all molecules
tested. This is further verified for all polymers and surfaces considered.
In particular, for periodic systems, results obtained on an infinite
glycine chain and on the wettability parameters of SiO2 surfaces are in good agreement with previously published data. The
size extensivity of the energetic terms involved in the electrostatic
contribution to the solvation energy is also well verified. These
encouraging results constitute a first step to take into account complex
environments in the CRYSTAL code, potentially allowing for a more
accurate modeling of complex processes for both periodic and nonperiodic
systems.