J. Chem. Phys. Abstract
Abstract
Mixed ab initio/empirical
force-field simulation studies, calculations in which
one part of the system is treated using a fully ab initio
description and another part is treated using an empirical description,
are becoming increasingly popular.
Here, the ability of the commonly used, plane wave based
generalized gradient approximation to density functional theory
is extended to model systems
in which the electrons are assumed to be localized in a single
small region of space, that is, itself, embedded within a large chemically
inert bath. This is accomplished by introducing
two length scales, so that the
rapidly varying, short range, electron-electron and electron-atom interactions
arising from the region where the electrons are localized
can be treated using an appropriately large plane wave basis while
the corresponding, slowly varying, long range interactions
of the electrons with the full system or bath,
can be treated using a small basis. Briefly,
a novel Cardinal B-spline based formalism is
employed to derive a smooth, differentiable, and rapidly convergent
(with respect to the small basis) expression for
the total electronic energy, which explicitly
contains the two length scales. The method
allows reciprocal space based techniques designed to
treat clusters, wires, surfaces and solids/liquids
(open, and 1D and 2D periodic boundary conditions, respectively) to
be utilized. Other plane wave based ``mixed ''methods are restricted
to clusters. The new methodology, which scales as N log(N)
at fixed
size of the chemically
active region, has been implemented for parallel computing platforms
and tested through applications to both model and realistic
problems including an enzyme, human carbonic anhydrase II solvated
in an explicit bath of water molecules.