21.10 More Advanced Treatments of Molecular Electronic Structure. Computational Chemistry 905
and that do not necessarily have conjugated systems of bonds. All of the valence-shell
electrons are included in the treatment, but inner-shell electrons are assumed to be
separately treated. A minimal set of basis functions is used that includes all atomic
orbitals in the valence shell of every atom.
The procedure is based on the variation method. The Hamiltonian for the valence
electrons is assumed to be a sum of effective one-particle Hamiltonians, which are not
explicitly represented. Approximations are invoked that differ somewhat from those
of the simple Hückel method. The electron–electron repulsive energy is neglected, but
the overlap integrals are explicitly calculated. The matrix elements of the effective
Hamiltonian, Eq. (H-5) of Appendix H, are approximated using various formulas.
The elements withab(the diagonal elements) are set equal to the valence-state
ionization potential (VSIP) of the given orbital, which is the energy required to remove
one electron from the valence shell of the atom. Wolfsberg and Helmholz approximated
the off-diagonal elements by the mean of the VSIP of each orbital times a fixed constant
times the overlap integral:
Hab
1
2
K
(
Haaeff+Hbbeff
)
Sab (21.10-1)
The constantKhas been assigned various values from 1 to 3. A value of 1.75 is
common. A slightly different version is employed by Ballhausen and Gray, who use
the geometric mean instead of the arithmetic mean in approximatingHab.^12
The extended Hückel method can be used to find the conformation of lowest energy
by repeated calculations with different conformations. Reasonable results are obtained,
and the resulting conformations are sometimes used as starting points for more sophis-
ticated calculations.
Exercise 21.21
Use a software package such as CAChe or Spartan to find the equilibrium (lowest-energy)
conformation for the following molecules, using the extended Hückel method:
a.H 2 CO (formaldehyde or methanal)
b.C 2 H 6 (ethane)
c.CH 3 COCH 3 (acetone or propanone)
The Pariser–Pople–Parr method
The Pariser–Pople–Parr method is the simplest implementation of the self-consistent
field method. Like the Hückel method, it treats only the electrons in delocalized pi
orbitals in planar molecules and represents these orbitals as linear combinations of
basis functions that include only the unhybridizedporbitals. All overlap integrals are
assumed to vanish, as in the Hückel method, but not all of the integrals representing
electron–electron repulsions are assumed to vanish. Two notations are used for these
integrals:
(rt|su)〈rt|
1
r 12
|su〉
∫∫
fr∗(1)f∗t(2)
1
r 12
fs(1)fu(2)dq 1 dq 2 (21.10-2)
(^12) C. J. Ballhausen and H. B. Gray,Molecular Orbital Theory, W. A. Benjamin, New York, 1964, p. 118.