A modified expression for the change in chemical potential of a solven
t, in a polymer network, due to isotropic swelling was obtained by sub
stituting a non-Gaussian chain length probability distribution in Flor
y's statistical analysis of rubber elasticity. The affine non-Gaussian
expression for the free energy change due to elastic deformation was
compared to both the traditional Flory and the James Guth ''phantom ne
twork'' expressions for the free energy change due to elastic deformat
ion using available experimental data for the swelling of highly cross
-linked polymeric resins. Among the different models for the elastic c
ontribution to the free energy change resulting from isotropic swellin
g, the non-Gaussian elasticity expression was found to be as good as,
or slightly better than the Flory expression, and clearly superior to
the James-Guth phantom network expression. Both of the two different e
xpressions used to represent the free energy of mixing, the Flory-Hugg
ins expression and a modified version of the quasi-chemical mixing exp
ression, were found to be equally successful when describing the isotr
opic swelling of cross-linked polymeric resins.