Viscoelastic phase separation (VPS) can be induced in dynamically asymmetric polystyrene/poly(vinyl methyl ether) (PS/PVME) blend in which there is a large difference between glass transition temperature of the components (about 125 degrees C). In this study, the effect of molecular weight of the slower component, PS, on VPS mechanism is investigated. The correlation between the time evolution of the phase-separating morphologies and their linear and nonlinear rheological behavior is studied for blends with three different PSs. Rheological measurements and morphological observations are carried out at quench depth of 14 degrees C. While it was previously found that depending on composition of blend, three different types of VPS behavior can be observed due to self-induced stresses in the early stage of phase separation-(i) the transient gel induced VPS (TG-VPS), (ii) coalescence induced VPS (C-VPS), and (iii) aggregating nucleation and growth (ANG)-in this study, we show that different types of VPS can be observed for a single composition by changing the molecular weight of PS. In other words, dynamic asymmetry between PS-rich and PVME-rich phases decreases with a decrease of molecular weight of PS which results in weaker transient gel in the early stage of phase separation. Consequently, the phase separation mechanism changes for 10/90 blend from TG-VPS to C-VPS and, for 5/95 blend from C-VPS to ANG or NNG (normal nucleation and growth). Furthermore, the variation of fractal dimension by phase separation is studied for 10/90 blends containing PS with different molecular weights. (C) 2017 The Society of Rheology.