c17 JWBS043-Rogers September 13, 2010 11:28 Printer Name: Yet to Come
276 THE VARIATIONAL METHOD: ATOMS
The same treatment produces a similar operator for electron 2:
Hˆ 2 =−^1
2 r 22
d
dr 2
r 22
d
dr 2
−
2
r 2
+
∫∞
0
φ 1
1
r 12
φ 1 dτ
We do not know theorbitalsof the electrons either. We can reasonably assume
that the ground state orbitals of electrons 1 and 2 are similar but not identical to the
1 sorbital of hydrogen:
φ 1 =
√
a^3
π
e−αr^1
and
φ 2 =
√
b^3
π
e−αr^2
The integral inHˆ 1 , representing the Coulombic interaction between electron 1 atr 1
and electron 2 somewhere in orbitalφ 2 , has been evaluated for Slater-type orbitals
(Rioux, 1987; McQuarrie, 1983) and is
V 1 =
∫∞
0
φ 2
1
r 12
φ 2 dτ=
1
r 1
[
1 −(1+br 1 )e−^2 br^1
]
Now the approximate Hamiltonian for electron 1 is
hˆ 1 =−^1
2 r 12
d
dr 1
r^21
d
dr 1
−
2
r 1
+
1
r 1
(
1 −( 1 +br 1 )e−^2 br^1
)
with a similar expression forhˆ 2 involvingar 2 in place ofbr 1 in the Slater orbital.
The orbital is normalized, so the energy of electron 1 is
E 1 =
∫∞
0
φ 1 hˆ 1 φ 1 dτ
with a similar expression forE 2.
CalculatingE 1 requires solution of three integrals:
E 1 =
∫∞
0
φ 1
(
−^12 ∇ 12
)
φ 1 dτ−
∫∞
0
φ 1
(
Z
r 1
)
φ 1 dτ+
∫∞
0
φ 1 (V 1 )φ 1 dτ
They yield (Rioux, 1987) three terms for the energy of the electron in orbitalφ 1 :
E 1 =
a^2
2
−Za+
ab
(
a^2 + 3 ab+b^2
)
(a+b)^3