Speck, T. (2024). Steady inhomogeneous shear flows as mechanical phase transitions. arXiv preprint arXiv:2411.11823v1.
This paper aims to provide a theoretical framework for understanding the emergence of inhomogeneous flows, specifically shear banding, in complex fluids by drawing parallels to mechanical phase transitions.
The author revisits models of fluids reaching a stationary state under mechanical equilibrium. They start with a non-local constitutive relation and apply the concept of a "mechanical phase transition." By introducing an integrating factor, they map the constitutive relation onto a dynamical system, analogous to systems in thermal equilibrium. The framework is then applied to two examples: shear banding in shear-thinning complex fluids and the coexistence of a solid with its sheared melt.
The paper concludes that inhomogeneous flows in complex fluids, including shear banding and solid-liquid coexistence under shear, can be effectively described as mechanical phase transitions. This approach avoids the inconsistencies encountered when generalizing free energy concepts to steady states and provides a robust framework for predicting and understanding these phenomena.
This research provides a novel perspective on inhomogeneous flows in complex fluids, offering a unified framework for understanding diverse phenomena like shear banding and solid-liquid coexistence under shear. The proposed approach, grounded in mechanical principles, circumvents the limitations of traditional thermodynamic descriptions and opens new avenues for studying and predicting the behavior of complex fluids far from equilibrium.
The current study focuses on the strain rate as the primary mechanical variable. Future research could extend this framework to incorporate additional variables, such as density and concentration, to account for more complex systems and phenomena. Further investigation into the development of accurate constitutive relations for specific materials will be crucial for applying this framework to real-world systems.
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by Thomas Speck kl. arxiv.org 11-19-2024
https://arxiv.org/pdf/2411.11823.pdfDybere Forespørgsler