1:X2" dX - ACS Publications - American Chemical Society

1:X2" dX = -. 2n + 1 giving. Im G(E'). dE'= C. dE(2n+'). The number of terms in the sum that are necessary for it to converge is clearly a function of...
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J . Phys. Chem. 1985,89, 925-930

can be taken outside of the integral, leaving us to only consider the integral over 1"'. Clearly, the integrals of odd functions of X about X = 0 will vanish. The only nonzero terms in the sum will thus be for n - 1 even, i.e., n odd, leaving us with Im G(E') c- d(2"+1) dE(2"+1)

"-0

I

1:X2"

Im G(E')

C

dE'=

dE(2n+')

The number of terms in the sum that are necessary for it to converge is clearly a function of how small 6 is, Le., how closely one approaches the pole. The principal value integral is thus computed in three parts: leading up to the pole, about the pole, and beyond the pole

dX

E'=€

"Im G(E')

where we have taken the integral about X = 0 from -6 to 6. The evaluation of this integral is straightforward: 262n+l dX = 2n 1

1:X2"

925

dE'=

Im G(E')

+

E'-E-dIm G(E? dE' E'- E dE'+

-

+

d(Z"+l)Im G(E')l

,,=o

dE