The effect of reaction rate on the morphology of reactive blends has been s
tudied using 75/25 (wt/wt) monocarboxylated polystyrene [PS-mCOOH]/poly(met
hyl methacrylate) [PMMA] with poly(methyl methacrylate-ran-glycidyl methacr
ylate) [PMMA-GMA] as an in-situ compatibilizer, by varying the amount of PM
MA-GMA in the blend, the molar concentration of GMA, C-GMA,C-0 in PMMA-GMA
at fixed molecular weight, and the molecular weight of PMMA-GMA at fixed C-
GMA,C-0. For the blends with PMMA-GMA having lower C-GMA,C-0, there exists
a critical amount of PMMA-GMA above which a sharp decrease in the surface a
rea average domain size (D-s) occurs. This amount was shifted to a smaller
value with increasing C-GMA,C-0 in PMMA-GMA. We demonstrated that the inter
facial graft reaction between PS-mCOOH and PMMA-GMA at 220 degreesC was des
cribed by the simple second-order reaction kinetics, i.e., mean field react
ion kinetics. From the morphological evolution, it is found that the morpho
logical change by an external flow from a pellet size to D-s with less than
1 mum occurred within a very short time of similar to 30 s. After this tra
nsition, coalescence is the main mechanism for determining the final morpho
logy obtained at a mixing time of 20 min. Finally, a master curve is obtain
ed when D-s is plotted against C-GMA,C-0, implying again that the concept o
f mean field reaction kinetics adequately applies to the blends employed in
this study.