- The first term (the integral of the density times the external potential) is
Z
r 0 ðrÞvðrÞdr¼
Z
r 0 ðr 1 Þ
X
nuclei A
"
ZA
r1A
"
dr 1 ¼"
X
nuclei A
ZA
Z
r 0 ðr 1 Þ
r1A
dr 1 (7.17)
We integrate the potential energy of attraction of each nucleus for an infinitesi-
mal portion of the charge cloud and sum for all the nuclei. If we knowr 0 the
integrals to be summed are readily calculated.
- The second term (the electronic kinetic energy of the noninteracting-electrons
reference system) is the expectation value of the sum of the one-electron kinetic
energy operators over the ground state multielectron wavefunction of the refer-
ence system (Parr and Yang explain this in detail [ 33 ]). Using the compact Dirac
notation for integrals:
hiT½r 0 ref¼ crj
X^2 n
i¼ 1
"
1
2
r^2 ijcr
*+
(7.18)
Since these hypothetical electrons are noninteractingcrcan be writtenexactly
(for a closed-shell system) as a single Slater determinant of occupied spin molecular
orbitals (Section 5.2.3.1). For arealsystem, the electrons interact and using a single
determinant causes errors due to neglect of electron correlation (Section 5.4), the
root of most of our troubles in wavefunction methods. Thus for a four-electron
system
cr¼
1
ffiffiffiffi
4!
p
cKS 1 ð 1 Það 1 Þ cKS 1 ð 1 Þbð 1 Þ cKS 2 ð 1 Það 1 Þ cKS 2 ð 1 Þbð 1 Þ
cKS 1 ð 2 Það 2 Þ cKS 1 ð 2 Þbð 2 Þ cKS 2 ð 2 Það 2 Þ cKS 2 ð 2 Þbð 2 Þ
cKS 1 ð 3 Það 3 Þ cKS 1 ð 3 Þbð 3 Þ cKS 2 ð 3 Það 3 Þ cKS 2 ð 3 Þbð 3 Þ
cKS 1 ð 4 Það 4 Þ cKS 1 ð 4 Þbð 4 Þ cKS 2 ð 4 Það 4 Þ cKS 2 ð 4 Þbð 4 Þ
(^)
(^)
(7.19)
The 16 spin orbitals in this determinant are theKohn–Sham spin orbitalsof the
reference system; each is the product of a Kohn–Sham spatial orbitalcKSi and a spin
functionaorb. Equation7.18can be written in terms of thespatialKS orbitals by
invoking a set of rules (the Slater–Condon rules [ 34 ]) for simplifying integrals
involving Slater determinants:
hiT½r 0 ref¼"
1
2
X^2 n
i¼ 1
cKS 1 ð 1 Þjr^21 jcKS 1 ð 1 Þ
(7.20)
The integrals to be summed are readily calculated. Note that DFTper sedoes not
involve wavefunctions, and the Kohn–Sham approach to DFT uses orbitals only as
a kind of subterfuge to calculate the noninteracting-system kinetic energy and the
electron density function; see below.
454 7 Density Functional Calculations