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MøllerPlessetPerturbationstheorie

MøllerPlessetPerturbationstheorie, commonly abbreviated MP perturbation theory, is a post-Hartree–Fock method in quantum chemistry that treats electron correlation by applying Rayleigh–Schrödinger perturbation theory to a Hartree–Fock reference wavefunction. Starting from the electronic Hamiltonian for fixed nuclei, one partitions the Hamiltonian into a zeroth-order Fock operator and a perturbation given by the fluctuation potential. Energy corrections E^(n) are computed, with E^(1)=0 for the MP scheme, so the leading correction is E^(2), called the MP2 correlation energy. Higher orders, MP3, MP4, etc., can be defined, but become progressively more expensive and less reliable; MP2 is by far the most widely used.

MP2 is reasonably accurate for many closed-shell systems and simple valence bonds and is size-extensive, but

Extensions include MPn based on a single determinant reference and various multireference MBPT approaches for near-degenerate

it
can
overbind
dispersion
forces
and
fail
for
bond
dissociation
or
near-degeneracy
situations.
The
method
is
non-variational
and
can
be
sensitive
to
the
choice
of
basis
set;
results
may
deteriorate
for
systems
with
strong
static
correlation.
situations.
In
modern
practice
MP,
especially
MP2,
has
largely
been
superseded
by
coupled-cluster
methods
(e.g.,
CCSD,
CCSD(T))
for
higher
accuracy,
though
MP2
remains
a
useful,
computationally
affordable
correction
in
many
calculations.