The second and the third virial coefficients of athermal polymer solutions

Scaling theory is applied to derive expressions describing the influence of polymolecularity on the second virial coefficient, A , , as obtained from osmotic pressure and light scattering measurements. Numerical values of polymolecularity correction factors are calculated for Schulz-Zimm and logarit

This note presents an efficient and fast method for evaluating the third virial coefficient for radially symmetric two-body potential functions. The computational method uses a list processing scheme based on a proper multidimensional integration formula and is considerably superior to the tradition

Based on the measurement of the concentration dependence of the osmotic pressure of sodium alginate aqueous solution in different concentrations of potassium nitrate, the contribution of polyion charges to the second virial coefficient was predicted. According to this analysis, an equation A 2 = A 2

## Abstract It is shown that the recently developed scaling theory for the second virial coefficient, __A__~2~, of dilute solutions of polymers with non‐uniform molecular weight distributions in a good solvent is able to explain in principle all seemingly contradictory observations reported in the

The segment-cloud model for polymer moIecuIes has been used, and the second virial coefficient AZ obtained as a function of the interaction parameter = for linear and branched chains having different values of 11. It is observed that the chain length effect, though much smakr than in the perturbatio

The Beth-Uhlenbeck formula is rederived using the notion of symmetrized and anti-symmetrized partition function introduced by Lee and Yang. By applying the method of complex angular momentum the summation of the phase shifts appearing in the formula is converted into an integral form. Consequently,