Slow Transients and Metastability in Wormlike Micelle Rheology

Journal De Physique Ii Pub Date : 1997-08-01 DOI:10.1051/JP2:1997172

C. Grand, J. Arrault, M. Cates

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引用次数: 111

Abstract

The steady-state nonlinear rheology of wormlike micellar systems is thought to be subject to shear banding (the underlying shear stress vs. strain rate curve σ(γ) is nonmonotonic). Shear banding may result in a plateau (σ(γ) = σp) in the measured flow curve (at controlled mean strain rate γ). We present new rheological data for aqueous CPyCl/NaSal (100 mM /60 mM). Steady-state flow curves published previously for this system (Rehage H. and Hoffmann H., Mol. Phys. 74 (1991) 933) have since been interpreted as shear-banded flow with top-jumping, in which the steady-state shear rate γ1 in the low shear band is the largest possible (γ 1 = γ 1 max , σ p = σ max ). That would rule out the existence of a metastable branch with a stress larger than σp. We show that such a branch does, however, exist (for temperatures in the range 20 - 25 °C). Similar results are found for a 100 mM/75 mM system. The time scale for relaxation of a metastable state onto true steady state flow, τ ss , is far longer than the Maxwell time of the fluid; this is consistent with shear banding. We observe τ ss ∼ (γ - γ c ) -P in the metastable regime (γ > γ 1 ), with p an exponent that depends on composition and temperature. The critical shear rate γ c is in some cases less than γ 1 so that no actual divergence of τ ss occurs. In at least one case, though, there is evidence for a physical divergence (γ c > γ 1 ) accompanied by a small window of shear rates, γ 1 < γ < γ c , for which τ ss is effectively infinite. In some respects the observed behaviour resembles that reported previously (Berret J.-F., Roux D.C. and Porte G., J. Phys. II Prance 4 (1994) 1261) for equimolar CPyCl/NaSal in 0.5 M NaCl. Those results were interpreted in terms of nucleation and growth of a shear-induced nematic phase. However the same explanation is unlikely for the low weight fractions (Φ ≤ 5%) used in our study.

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蠕虫状胶束流变的慢瞬态和亚稳态

蠕虫状胶束体系的稳态非线性流变被认为服从于剪切带(潜在的剪切应力-应变率曲线σ(γ)是非单调的)。在控制的平均应变率γ下，剪切带可能导致流动曲线出现平台(σ(γ) = σp)。我们提出了新的CPyCl/NaSal (100 mM /60 mM)的流变学数据。先前发表的稳态流动曲线(Rehage H.和Hoffmann H.， Mol. Phys. 74(1991) 933)被解释为具有顶跃的剪切带流动，其中低剪切带的稳态剪切速率γ1可能最大(γ 1 = γ1 max， σ p = σ max)。这将排除应力大于σp的亚稳分支的存在。然而，我们表明，这样的分支确实存在(温度在20 - 25°C范围内)。在100毫米/75毫米系统中发现了类似的结果。亚稳态弛豫到真正稳态流动的时间尺度τ ss远长于流体的麦克斯韦时间;这与剪切带一致。我们观察到τ ss ~ (γ - γ c) - p处于亚稳区(γ > γ 1)， p是一个指数，取决于成分和温度。在某些情况下，临界剪切速率γ c小于γ 1，因此τ ss不会发生实际的发散。然而，至少在一种情况下，有证据表明物理散度(γ c > γ 1)伴随着一个小的剪切率窗口，γ 1 < γ < γ c，其中τ ss实际上是无限的。在某些方面，观察到的行为与以前报道的相似(贝雷特j - f。， Roux D.C.和Porte G.， J. Phys。II Prance 4(1994) 1261)在0.5 M NaCl中测定等摩尔CPyCl/NaSal。这些结果被解释为剪切诱导的向列相的成核和生长。然而，同样的解释不太可能用于我们研究中使用的低权重分数(Φ≤5%)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal De Physique Ii

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