Measurements of average free volume hole sizes, (v(f)), and the fractional free volumes, f(ps), in vulcanized cis-polyisoprene (CPI), high-vinyl polybutadiene (HVBD), and their 50:50 blend were made via determination of orthopositronium annihilation lifetimes. The results are compared to corresponding data on the uncured materials. On crosslinking, (v(f)) decreases in the rubbery state but remains essentially unchanged in the glass. This is consistent with the expectation that the crosslinks greatly restrict the thermal expansion of the chains above the glass transition temperature (T-g) but have less influence on the packing density in the glass. Scaling relationships between (v(f)), f(ps), the thermal expansion coefficient alpha(f) = df(ps)/dt, and T-g are examined. We find that (v(f))(g) the hole volume at T-g, and f(ps),(g), the fractional free volume at T-g, each increase significantly with increasing T-g. This behavior is consistent with previous observations reported in the literature and has been interpreted as a manifestation of the kinetic character of the glass transition. High-T-g polymers need a larger free volume to pass into the liquid state. The change in expansion coefficient on passing from the glass to the liquid, Delta alpha(f) = alpha(f,l) - alpha(f,g), increases slowly with T-g, as predicted by free volume theory.