Abstract

Abstract The development of the shear stress at the start of shear flow at constant rate of shear κ was measured for polystyrene solutions in diethyl phthalate with a cone‐and‐plate rheometer. Ranges of molecular weight M and concentration c were 3.10 × 10 6 −7.62 × 10 6 and 0.112−0.329 g/cm 3 , respectively. The shear stress as a function of time t exhibited a marked maximum at large κ when either M or c was relatively low. When M and c were high, the maximum was broad and low. In a few extreme cases no maximum was observed in the range of κ studied. The constitutive model of Bernstein, Kearsley, and Zapas could describe approximately the shear stresses at a sudden start and on cessation of steady shear flow with a memory function evaluated from the strain‐dependent relaxation modulus. The strain dependence of the memory function for solutions of low M or c was approximately expressed as exp{−α| s |} where α is a constant ( ca . 0.37) and | s | is the absolute value of shear strain. When M and c were high, the strain dependence was found to be more diffuse and to require several terms if approximated by exponential functions of | s |. The Lodge model based on a strain‐rate dependent relaxation spectrum was not able to describe the strain‐dependent relaxation modulus as well as the interrelation between shear stresses at a sudden start and a cessation of steady shear flow.