Toughening of epoxy/polycaprolactone composites via reaction induced phase separation

A series of melt processable thermoset/thermoplastic blends were prepared by mixing bisphenol-A diglycidyl ether (Epon-828)/diaminodiphenyl sulfone (DGEBA/DDS) system with two grades of polycaprolactone resin. Phase separation behavior of the blends was investigated by means of optical microscopy, microstructure by scanning electron microscopy (SEM), and thermo-mechanical properties. The toughness of polycaprolactone modified epoxies was measured by instrumented falling weight impact (IFWI) testing. Various blend morphologies were observed depending upon the cured epoxy network/thermoplastic composition. Spinodal decomposition as characterized by modulated structure of unique periodicity and phase connectivity was found to be the probable mechanism of phase separation. SEM examination of fracture surfaces indicated a strong adhesion between the epoxy-rich and polycapralactone-rich phases. Optimum improvement in failure energy was obtained for the compositions containing 10-20% polycaprolactone without significantly compromising the elastic modulus and the thermo-mechanical stability of the epoxy. Ln light of morphological evidences, a possible toughening effect was postulated in terms of tearing of the thermoplastic component and induced plastic deformation of the epoxy matrix.