Rubber-modified glassy amorphous polymers prepared via chemically induced phase separation. 2. Mode of microscopic deformation studied by in-situ small-angle X-ray scattering during tensile deformation

The mode of microscopic deformation in rubber-modified amorphous polymers h as been investigated by small-angle X-ray scattering during tensile deforma tion. Synchrotron experiments were performed for blends consisting of poly( methyl methacrylate) (PMMA) with a finely dispersed rubbery epoxy phase. Th ese blends were prepared via chemically induced phase separation, as shown in the first paper of this series. On macroscopic deformation these blends show that the toughness of brittle amorphous polymers can be significantly enhanced by the introduction of submicron size rubber particles. The object ive of the present study is to establish the relationship between the morph ology and the macroscopic mechanical properties of the blends. As observed for neat PMMA, crazing is found to occur for the macroscopically brittle PM MA/epoxy 90/10 blend. In contrast, the ductile blend with 20 wt % epoxy def orms via shear yielding which is preceded by cavitation. Shear yielding als o occurs for blends having even higher epoxy contents, although it is not a ccompanied by the occurrence of dilatation processes. The changes in the sc attering patterns during deformation are attributed to morphological change s like orientation. Cross-linking of the epoxy phase appears to have an imp ortant influence on the mode of microscopic deformation. A blend with 20 wt % un-cross-linked epoxy appears to deform via crazing instead of cavitatio n. The change in deformation mechanism is associated with the plasticizatio n of crazes on a local level.. The local strain is defined as the local def ormation of the sample exposed to the incident beam as measured by recordin g the beam intensity in front of, and after, the sample during the drawing process. Thus, the local strain in the beam can accurately be measured and related to the corresponding scattering patterns. The local strain values o btained are in agreement with those from macroscopic tensile tests.