Ls. Loo et al., Deuterium nuclear magnetic resonance of Phenol-d(5) in nylon 6 under active uniaxial deformation, MACROMOLEC, 32(13), 1999, pp. 4359-4364
A stretching device suitable for fitting within a deuterium nuclear magneti
c resonance (NMR) probe was constructed to investigate the large strain uni
axial tensile deformation behavior of nylon 6 plasticized by 40 wt % of phe
nol-d(5). The phenol-d(5) molecules probe the environment of the amorphous
regions in nylon 6; the phenol-d(5) molecules do not exist in a "free" stat
e, and they remain associated with the amide groups by hydrogen bonding dur
ing deformation. Deuterium NMR spectra show that the quadrupolar splitting
varies Linearly with strain throughout the experiment, indicating that the
orientation of the phenol-d(5) molecules in the amorphous phase is simply a
function of strain and not of stress. The line width increases with strain
at low-to-moderate strains but attains a constant value at large strains (
in the strain-hardening regime). From low-to-moderate strains, the line wid
th behavior arises from a decrease in the translational motion of the pheno
l-d(5) molecules between amide groups in the amorphous chains during elasti
c deformation and during the transformation of the lamellar structure of ny
lon 6 to a fibrillar one. At large strains, the existence and deformation o
f the fibrillar structure cause the phenol-d(5) molecules to be confined to
their respective amide groups on the time scale of the NMR measurement (si
milar to 0.1 ms), resulting in a constant line width.