c20 JWBS043-Rogers September 13, 2010 11:29 Printer Name: Yet to Come
THE GAUSSIAN BASIS SET 325
The next step is to take two Gaussian functions, calledprimitives, parameterized
so that one fits the STO close to the nucleus and the other contributes to the part away
from the nucleus. We seek a function
STO-2G=C 1 e−α^1 r
2
+C 2 e−α^2 r
2
But how shall we apportion this linear combination so that we have one tall basis
function contributing to the orbital near the nucleus and one for a “fat” tail? Let us take
α 1 = 1 .0 andα 2 = 0 .25. BothC 1 e−r
2
andC 2 e−^0.^25 r
2
contribute to the sum. The larger
negative exponent is tall near the nucleus but drops off faster than the small negative
exponent. Nowφ(r) will extend to larger values ofrand give us the fat tail we seek:
φ(r)=C 1 e−r
2
+C 2 e−^0.^25 r
2
But we still have two parameters to worry aboutC 1 andC 2. They control the relative
contribution of each primitive to the final wave function. Let us take a 60/40 split and
favor the fat tail:
φ(r)= 0. 40 e−^1.^0 r
2
+ 0. 60 e−^0.^25 r
2
We now have a four-parameter basis set for use with thegenkeyword (File 20.1).
They are entered in the format
α 1 C 1
α 2 C 2
The GAUSSIAN©Cinput file becomes File 20.1. The STO curve fit is shown in
Fig. 20.5.
STO(r):=e−r
φ(r):= 0. 40 e−^1.^0 r
2
+ 0. 60 e−^0.^25 r
2
.
# gen
hatom gen
02
h
1
S2
1.0 0.40
0.25 0.60
****
FILE 20.1 (Input) A four-parameter Gaussian File for the hydrogen atom. Line 8 designates
the first center (the only one in this case) and line 9 identifies it as an s orbital with 2 basis
functions.