Yielding and bifurcated aging in nanofibrillar networks

arXiv: Soft Condensed Matter Pub Date : 2020-07-24 DOI:10.1103/physrevmaterials.4.102601

R. Poling-Skutvik, Eóin McEvoy, V. Shenoy, C. Osuji

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引用次数: 4

Abstract

The yielding of disordered materials is a complex transition involving significant changes of the material's microstructure and dynamics. After yielding, many soft materials recover their quiescent properties over time as they age. There remains, however, a lack of understanding of the nature of this recovery. Here, we elucidate the mechanisms by which fibrillar networks restore their ability to support stress after yielding. Crucially, we observe that the aging response bifurcates around a critical stress $\sigma_\mathrm{c}$, which is equivalent to the material yield stress. After an initial yielding event, fibrillar networks subsequently yield faster and at lower magnitudes of stress. For stresses $\sigma \sigma_\mathrm{c}$, the yield time instead plateaus at a finite value because the developed network density is insufficient to support the applied stress. We quantitatively relate the yielding and aging behavior of the network to the competition between stress-induced disentanglement and dynamic fluctuations of the fibrils rebuilding the network. The bifurcation in the material response around $\sigma_c$ provides a new possibility to more rigorously localize the yield stress in disordered materials with time-dependent behavior.

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纳米纤维网络的屈服和分叉老化

无序材料的屈服是一个复杂的转变过程，涉及材料微观结构和动力学的重大变化。在屈服之后，随着时间的推移，许多软材料会恢复其静态特性。然而，人们对这次复苏的性质仍然缺乏了解。在这里，我们阐明了纤维网络在屈服后恢复其支持应力的能力的机制。至关重要的是，我们观察到老化响应在临界应力$\sigma_\ mathm {c}$周围分岔，该应力相当于材料的屈服应力。在初始屈服事件之后，纤维网络随后以更快的速度和更低的应力强度屈服。对于应力$\sigma \sigma_\mathrm{c}$，屈服时间在有限值处趋于稳定，因为发达的网络密度不足以支持施加的应力。我们定量地将网络的屈服和老化行为与应力诱导的解缠和重建网络的原纤维的动态波动之间的竞争联系起来。材料响应在$\sigma_c$附近的分岔为更严格地定位具有时间依赖行为的无序材料的屈服应力提供了新的可能性。

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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arXiv: Soft Condensed Matter

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