We study the elasto-capillary self-thinning and ultimate breakup of three polystyrene-based ideal
elastic fluids by measuring the evolution in the filament diameter as slender viscoelastic threads
neck and eventually break. We examine the dependence of the transient diameter profile and the
time to breakup on the molecular weight, and compare the observations with simple theories for
breakup of slender viscoelastic filaments. The evolution of the transient diameter profile predicted
by a multimode FENE-P model quantitatively matches the data provided the initial stresses in the
filament are taken into account. Finally, we show how the transient uniaxial extensional viscosity of
a dilute polymer solution can be estimated from the evolution in the diameter of the necking
filament. The resulting ‘‘apparent extensional viscosity’’ profiles are compared with similar results
obtained from a filament stretching rheometer. Both transient profiles approach the same value for
the steady state extensional viscosity, which increases with molecular weight in agreement with the
Rouse–Zimm theory. The apparent discrepancy in the growth rate of the two transient curves can
be quantitatively explained by examining the effective stretch rate in each configuration. Filament
thinning studies and filament stretching experiments thus form complementary experiments that
lead to consistent measures of the transient extensional viscosity of a given test fluid.