Crystal orientation in a semicrystalline polymer in relation to deformation of polymer spherulites. IV. Crystal orientation mechanism of nylon‐6 under uniaxial stretching

Abstract

AbstractA model relating crystal orientation to the deformation of nylon‐6 spherulites under uniaxial stretching is discussed in terms of the orientation distribution functions of reciprocal lattice vectors of crystal planes, such as the (002) and (200) planes. The distribution functions calculated from the model are compared with those obtained from x‐ray diffraction experiments. It is found that the crystalaaxis and, consequently, the direction of hydrogen bonds within the crystal (α modification) orient parallel to the lamellar axis in the undeformed state, and that the crystal orientation behavior of nylon‐6 is much different from that of low‐density polyethylene, being characterized by much smaller values of the reorientation parameters of crystallites within orienting lamellae.Moreover, small‐angle light scattering forHvandVvpolarization is also calculated on the basis of the spherulite deformation model by taking the nylon‐6 crystal as having orthogonal–biaxial symmetry in optical anisotropy. It is concluded that theHvscattering can be realized in terms of the proposed model for spherulite deformation by taking into account a considerable contribution of hydrogen bonds to the molecular polarizability, so as to make the polarizability along the crystalaaxis larger than that along thebaxis. In other words, this conclusion suggests positively birefringent spherulites in the nylon‐6 samples studied.