Abstract
We revisit the classical problem of the viscoelastic response of nematic (liquid crystal) polymers to small amplitude oscillatory shear. A multiple time scale perturbation analysis is applied to the Doi–Hess mesoscopic orientation tensor model to describe key features observed of longtime experiments, both physical (Moldenaers and Mewis, J Rheol, 30:567–584, 1986; Larson and Mead, J Rheol, 33:1251–1281, 1989b) and numerical (herein). First, there is a very slow time scale drift in the envelope of oscillations of the major director; we characterize the mean director angle and the envelope of oscillation. Second, there are bistable asymptotic orientational states, distinguished in that they are precisely the zero-stress orientational distributions noted in Larson and Mead (J Rheol, 33:185–206, 1989a). Third, the drift dynamics and asymptotic mean director angle are determined by the initial orientation of the director, not by material properties; we characterize the domain of attraction of each bistable state. Finally, the director drift leads to a predicted longtime decrease in the storage and loss moduli, consistent with experimental observations.
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Notes
The generalization of this analysis to full tensor degrees of freedom leads to a five-dimensional dynamical system, which was not yet analytically solved.
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Choate, E.P., Forest, M.G. A classical problem revisited: rheology of nematic polymer monodomains in small amplitude oscillatory shear. Rheol Acta 46, 83–94 (2006). https://doi.org/10.1007/s00397-006-0094-2
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DOI: https://doi.org/10.1007/s00397-006-0094-2