c15 JWBS043-Rogers September 13, 2010 11:28 Printer Name: Yet to Come
244 EARLY QUANTUM THEORY: A SUMMARY
The GAUSSIAN©C program, using a restricted Hartree–Fock procedure, RHF
yields
SCF Done: E(RHF) =-2.80778395662 A.U. after 1 cycles
The value after four cycles by a program named G3 (to be discussed in more detail
later) gives
SCF Done: E(RHF) =-2.85516042615 A.U. after 4 cycles
A Hartree–Fock triple zeta calculation (a linear combination involving three ad-
justableZparameters) gives
SCF Done: E(RHF) =-2.85989537425 A.U. after 3 cycles
The energy – 2.860Ehagrees with the experimental value to within 1.5%.
Example 15.2
The Hamiltonian function for the ground state hydrogen atom (with angular momen-
tum equal to zero) is
Hˆ =−
2
2 me
∇^2 +
e^2
r
=−
^2
2 me
r^2
∂^2
∂r^2
−
e^2
4 π^2 ε 0 r
=−
^2
2 mer
d
dr
(
r^2
∂^2
∂r^2
)
−
e^2
4 π^2 ε 0 r
where there is noθ,φterm because there is no angular momentum in the ground
state and∇^2 =r^2 (∂^2 /∂r^2 )=r^2 (d^2 /dr^2 ) for this one-dimensional operator in which
r^2 appears because the radius vector may be oriented in any direction toward a
surface element of a sphere. The surface area of a sphere goes up as the square of the
radiusA= 4 πr^2 .The4π^2 ε 0 in the denominator of the potential energy arises in the
same way, where 4π^2 ε 0 is the permittivity of free space (essentially a proportionality
constant between coulombs and joules).
Allowing this operator to operate on the trial functionφ=e−αrgives, from the
Schr ̈odinger equation (Hˆφ=Eφ),
[
−
^2
2 mer
d
dr
(
r^2
d^2
dr^2
)
−
e^2
4 π^2 ε 0 r
]
φ(r)=Eφ(r)