Thermally stimulated current (TSC) was used to study molecular relaxations in polyethylene terephthalate (PET) bottles. Unstretched PET film, which was used as a model for the bottle preform, exhibited two peaks at 77 and 90 degrees C that correspond to the alpha and rho relaxation processes, respectively. The bottles exhibited only the rho relaxation, which is located within the temperature range for blow molding PET bottles. The alpha peak is associated with the main glass transition temperature (T-g) and the rho peak may be associated with a second T-g. The second T-g is attributed to a "constrained state," which shows dipolar behavior. Heat-shrinkage behavior was examined at 90 degrees C. The maximum TSC (I-m) of the rho peak decreased with increasing heat set temperature, and with decreasing shrinkage. Bottles blown at 113 degrees C showed a lower I-m and shrinkage than those blown at 103 degrees C for equivalent heat set temperatures. The higher blowing temperature allowed a higher stretch speed that produced higher crystallinity bottles with self-heat generation during rapid deformation. A relationship between. the shrinkage mechanism and the dipole relaxation was proposed.