Within

computational chemistry Computational chemistry is a branch of chemistry that uses computer simulation to assist in solving chemical problems. It uses methods of theoretical chemistry, incorporated into computer programs, to calculate the structures and properties of m ...

, the Slater–Condon rules express integrals of one- and two-body operators over

wavefunction A wave function in quantum physics is a mathematical description of the quantum state of an isolated quantum system. The wave function is a complex-valued probability amplitude, and the probabilities for the possible results of measurements mad ...

s constructed as

Slater determinant In quantum mechanics, a Slater determinant is an expression that describes the wave function of a multi-fermionic system. It satisfies anti-symmetry requirements, and consequently the Pauli principle, by changing sign upon exchange of two electro ...

s of

orthonormal In linear algebra, two vectors in an inner product space are orthonormal if they are orthogonal (or perpendicular along a line) unit vectors. A set of vectors form an orthonormal set if all vectors in the set are mutually orthogonal and all of un ...

orbitals in terms of the individual orbitals. In doing so, the original integrals involving ''N''-electron wavefunctions are reduced to sums over integrals involving at most two molecular orbitals, or in other words, the original 3''N'' dimensional integral is expressed in terms of many three- and six-dimensional integrals. The rules are used in deriving the working equations for all methods of approximately solving the Schrödinger equation that employ wavefunctions constructed from Slater determinants. These include Hartree–Fock theory, where the wavefunction is a single determinant, and all those methods which use Hartree–Fock theory as a reference such as

Møller–Plesset perturbation theory Møller–Plesset perturbation theory (MP) is one of several quantum chemistry post–Hartree–Fock ab initio methods in the field of computational chemistry. It improves on the Hartree–Fock method by adding electron correlation effects by m ...

, and

Coupled cluster Coupled cluster (CC) is a numerical technique used for describing many-body systems. Its most common use is as one of several post-Hartree–Fock ab initio quantum chemistry methods in the field of computational chemistry, but it is also used in ...

and

Configuration interaction Configuration interaction (CI) is a post-Hartree–Fock linear variational method for solving the nonrelativistic Schrödinger equation within the Born–Oppenheimer approximation for a quantum chemical multi-electron system. Mathematical ...

theories. In 1929

John C. Slater John Clarke Slater (December 22, 1900 – July 25, 1976) was a noted American physicist who made major contributions to the theory of the electronic structure of atoms, molecules and solids. He also made major contributions to microwave electroni ...

derived expressions for diagonal matrix elements of an approximate Hamiltonian while investigating atomic spectra within a perturbative approach. The following year

Edward Condon Edward Uhler Condon (March 2, 1902 – March 26, 1974) was an American nuclear physicist, a pioneer in quantum mechanics, and a participant during World War II in the development of radar and, very briefly, of nuclear weapons as part of the ...

extended the rules to non-diagonal matrix elements. In 1955

Per-Olov Löwdin Per-Olov Löwdin (October 28, 1916 – October 6, 2000) was a Swedish physicist, professor at the University of Uppsala from 1960 to 1983, and in parallel at the University of Florida until 1993. A former graduate student under Ivar Waller, Löwd ...

further generalized these results for wavefunctions constructed from non-orthonormal orbitals, leading to what are known as the Löwdin rules.

Mathematical background

In terms of an antisymmetrization operator (

\mathcal

) acting upon a product of ''N'' orthonormal

spin-orbital In atomic theory and quantum mechanics, an atomic orbital is a function describing the location and wave-like behavior of an electron in an atom. This function can be used to calculate the probability of finding any electron of an atom in any spe ...

s (with r and ''σ'' denoting spatial and spin variables), a determinantal wavefunction is ''denoted'' as :

, \Psi\rangle = \mathcal(\phi_(\mathbf_\sigma_)\phi_(\mathbf_\sigma_)\cdots\phi_(\mathbf_\sigma_)\phi_(\mathbf_\sigma_)\cdots\phi_(\mathbf_\sigma_)).

A wavefunction differing from this by only a single orbital (the ''mth orbital) will be denoted as :

, \Psi_^\rangle = \mathcal(\phi_(\mathbf_\sigma_)\phi_(\mathbf_\sigma_)\cdots\phi_(\mathbf_\sigma_)\phi_(\mathbf_\sigma_)\cdots\phi_(\mathbf_\sigma_)),

and a wavefunction differing by two orbitals will be denoted as :

, \Psi_^\rangle = \mathcal(\phi_(\mathbf_\sigma_)\phi_(\mathbf_\sigma_)\cdots\phi_(\mathbf_\sigma_)\phi_(\mathbf_\sigma_)\cdots\phi_(\mathbf_\sigma_)).

For any particular one- or two-body operator, ''Ô'', the Slater–Condon rules show how to simplify the following types of integrals: :

\langle\Psi, \hat, \Psi\rangle, \langle\Psi, \hat, \Psi_^\rangle,\ \mathrm\ \langle\Psi, \hat, \Psi_^\rangle.

Matrix elements for two wavefunctions differing by more than two orbitals vanish unless higher order interactions are introduced.

Integrals of one-body operators

One body operators depend only upon the position or momentum of a single electron at any given instant. Examples are the

kinetic energy In physics, the kinetic energy of an object is the energy that it possesses due to its motion. It is defined as the work needed to accelerate a body of a given mass from rest to its stated velocity. Having gained this energy during its accele ...

, dipole moment, and

total angular momentum In quantum mechanics, the total angular momentum quantum number parametrises the total angular momentum of a given particle, by combining its orbital angular momentum and its intrinsic angular momentum (i.e., its spin). If s is the particle's s ...

operators. A one-body operator in an ''N''-particle system is decomposed as :

\hat = \sum_^\ \hat(i).

The Slater–Condon rules for such an operator are: :

\begin
\langle\Psi, \hat, \Psi\rangle &= \sum_^\ \langle\phi_, \hat, \phi_\rangle, \\
\langle\Psi, \hat, \Psi_^\rangle &= \langle\phi_, \hat, \phi_\rangle, \\
\langle\Psi, \hat, \Psi_^\rangle &= 0.
\end

Integrals of two-body operators

Two-body operators couple two particles at any given instant. Examples being the electron-electron repulsion, magnetic dipolar coupling, and total angular momentum-squared operators. A two-body operator in an ''N''-particle system is decomposed as :

\hat = \frac 12 \sum_^\sum_^\ \hat(i,j).

The Slater–Condon rules for such an operator are: :

\begin
\langle\Psi, \hat, \Psi\rangle &= \frac\sum_^\sum_^\ \bigg(\langle\phi_\phi_, \hat, \phi_\phi_\rangle - \langle\phi_\phi_, \hat, \phi_\phi_\rangle\bigg), \\
\langle\Psi, \hat, \Psi_^\rangle &= \sum_^\ \bigg(\langle\phi_\phi_, \hat, \phi_\phi_\rangle - \langle\phi_\phi_, \hat, \phi_\phi_\rangle\bigg), \\
\langle\Psi, \hat, \Psi_^\rangle &= \langle\phi_\phi_, \hat, \phi_\phi_\rangle - \langle\phi_\phi_, \hat, \phi_\phi_\rangle,
\end

where :

\langle\phi_\phi_, \hat, \phi_\phi_\rangle = \int\mathrm\mathbf\int\mathrm\mathbf'\ \phi_^(\mathbf)\phi_^(\mathbf')g(\mathbf,\mathbf')\phi_(\mathbf)\phi_(\mathbf').

Any matrix elements of a two-body operator with wavefunctions that differ in three or more spin orbitals will vanish.

References

{{DEFAULTSORT:Slater-Condon rules Computational chemistry Quantum chemistry