The many-body expansion (MBE) for a system of monomers is given by
(12.69) |
in which represents the energy of monomer , =
is a two-body correction for dimer , and
=
is a three-body correction
for trimer , etc. In a large system and/or a large basis set, truncation
of this expression at the two- or three-body level may dramatically reduce the
amount of computer time that is required to compute the energy. Convergence of
the MBE can be accelerated by embedding the monomer (), dimer
(), trimer (), calculations in some representation of
the electrostatic potential of the rest of the system. A simple means to do
this is via atom-centered point charges that could be obtained when the
terms are calculated; this is the so-called electrostatically-embedded
many-body expansion
(EE-MBE),
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which we will denote as EE-MBE() when the expansion is truncated at -body terms.
MBE() and EE-MBE() are available in Q-Chem, with analytic gradients, up
to five-body terms ().
It is well known that the interaction energies of non-covalent clusters are
usually overestimated—often substantially—owing to basis-set superposition
error (BSSE), which disappears only very slowly as the basis sets approach
completeness. The widely used Boys-Bernardi counterpoise procedure corrects
for this by computing all energies, cluster and individual monomers, using the
full cluster basis set. (In clusters with more than two monomers, the obvious
generalization of the Boys-Bernardi counterpoise correction is sometimes called
the “site–site function counterpoise” correction or SSFC.) Note, however,
that basis-set extrapolation is still necessary for high-quality binding
energies. In , for example, a counterpoise-corrected MP2/aug-cc-pVQZ calculation is still kcal/mol from the MP2 basis-set
limit.
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Fortunately, the MBE allows for use of large basis
sets in order to perform basis-set extrapolations in sizable
clusters,
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and one can employ a counterpoise
correction that is consistent with an -body expansion in order to obtain an
-body approximation to the Boys-Bernardi counterpoise-corrected supersystem
energy. Two such corrections have been proposed: the many-body counterpoise
correction, MBCP(),
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4,
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and the -body
Valiron-Mayer function counterpoise correction, VMFC().
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The two approaches are equivalent for but the MBCP() method requires
far fewer subsystem calculations starting at and is thus significantly
cheaper, while affording very similar results as compared to
VMFC().
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