Introduction
For the simplest single bond, found in the H2 molecule, molecular orbitals can always be written in terms of two functions χiA and χiB (which are atomic orbitals with small corrections) located at the two nuclei,
where Ni is a normalization constant. The ground state wavefunction for H2 at the equilibrium geometry is dominated by the configuration (φ1)2, which means the molecular orbital φ1 is nearly doubly occupied. The Hartree–Fock model assumes it is doubly occupied, which leads to a total wavefunction of
where Θ2,0 is the singlet (S = 0) spin function for two electrons. The molecular orbitals in this case φ1 are taken as sums of 1s atomic orbitals on both atoms, namely N1(1sA + 1sB). Expanding the above equation into atomic orbitals yields
This Hartree-Fock model gives a reasonable description of H2 around the equilibrium geometry - about 0.735Å for the bond length (compared to a 0.746Å experimental value) and 84 kcal/mol for the bond energy (exp. 109 kcal/mol). This is typical of the HF model, which usually describes closed shell systems around their equilibrium geometry quite well. At large separations, however, the terms describing both electrons located at one atom remain, which corresponds to dissociation to H+ + H−, which has a much larger energy than H + H. Therefore, the persisting presence of ionic terms leads to an unphysical solution in this case.
Consequently, the HF model cannot be used to describe dissociation processes with open shell products. The most straightforward solution to this problem is introducing coefficients in front of the different terms in Ψ1:
which forms the basis for the valence bond description of chemical bonds. With the coefficients CIon and CCov varying, the wave function will have the correct form, with CIon=0 for the separated limit and CIon comparable to CCov at equilibrium. Such a description, however, uses non-orthogonal basis functions, which complicates its mathematical structure. Instead, multiconfiguration is achieved by using orthogonal molecular orbitals. After introducing an anti-bonding orbital
the total wave function of H2 can be written as a linear combination of configurations built from bonding and anti-bonding orbitals:
where Φ2 is the electronic configuration (φ2)2. In this multiconfigurational description of the H2 chemical bond, C1 = 1 and C2 = 0 close to equilibrium, and C1 will be comparable to C2 for large separations.
Read more about this topic: Multi-configurational Self-consistent Field
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