words, we are counting each repulsion twice. The simple sum thus represents
properly the total kinetic and electron–nuclear attraction potential energy, but over-
counts the electron–electron repulsion potential energy (recall that we are working
with 2nelectrons and thusnfilled MOs):
EðoverestimatedÞ¼ 2Xni¼ 1ei ð 5 : 84 ÞNote that we cannot just take half of this simple sum, because only the electron–
electron energy terms, not all the terms, have been doubly-counted. The solution is
to subtract from 2∑ethe superfluous repulsion energy; from our discussion
of Eq.5.50inSection 5.2.3.5we saw that the sum∑(2J#K) overnrepresents
the repulsion energy of one electron interacting with all the other electrons, so to
remove the superfluous interactions we subtract∑∑(2J#K), the sum overnof the
repulsion energy sum, to get [ 15 ]
EHF¼ 2
Xni¼ 1ej#Xni¼ 1Xnj¼ 1ð 2 Jijð 1 Þ#Kijð 1 ÞÞð 5 : 85 ÞEHFis the Hartree–Fock electronic energy: the sum of one-electron energies
corrected (within the average-field HF approximation) for electron–electron repul-
sion. We can get rid of the integralsJandKover MO’scand obtain an equation for
EHFin terms ofc’s andf’s. From (5.83),
Xni¼ 1Xnj¼ 1ð 2 Jijð 1 Þ#Kijð 1 ÞÞ¼Xni¼ 1eiþXni¼ 1Hcoreiiand from this and (5.85) we get
EHF¼
Xni¼ 1eiþXni¼ 1Hiicore ð 5 : 86 ÞFrom the definition ofHcoreii in Eqs.5.49and5.50, i.e. fromHcoreii ¼ cið 1 ÞjH^core
jciDE
ð 5 : 87 Þand the LCAO expansion (5.52)
ci¼Xms¼ 1csifs ð 5 : 88 ¼ 5 : 52 Þ5.2 The Basic Principles of the ab initio Method 211