Scaling laws for passive polymer dynamics in active turbulence

Zahra K. Valei; Tyler N. Shendruk

doi:10.1103/w3gp-knnp

Scaling laws for passive polymer dynamics in active turbulence

Zahra K. Valei, Tyler N. Shendruk

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

Abstract

Biological systems commonly combine intrinsically out-of-equilibrium active components with passive polymeric inclusions to produce unique material properties. To explore these composite systems, idealized models - such as polymers in active fluids - are essential to develop a predictive theoretical framework. We simulate a single, freely jointed passive chain in two-dimensional active turbulence. Active flows advect the polymer, producing a substantially enhanced diffusivity. Our results reveal that the dimensionless diffusivity obeys scaling laws governed by the P\'eclet, Weissenberg, and Ericksen numbers, which paves the way for designing active/polymeric hybrid materials with predictable properties that differ significantly from those of nondeformable inclusions.

Original language	English
Article number	138301
Pages (from-to)	1-10
Number of pages	10
Journal	Physical Review Letters
Volume	135
Issue number	13
Early online date	24 Sept 2025
DOIs	https://doi.org/10.1103/w3gp-knnp
Publication status	Published - 26 Sept 2025

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10.1103/w3gp-knnpLicence: Creative Commons: Attribution (CC-BY)

https://arxiv.org/abs/2503.19985Licence: Creative Commons: Attribution (CC-BY)

[LC]2: 'Living' Colloidal Liquid Crystals
Shendruk, T. (Principal Investigator)
European Commission
1/08/20 → 31/05/25
Project: Research

Cite this

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title = "Scaling laws for passive polymer dynamics in active turbulence",

abstract = " Biological systems commonly combine intrinsically out-of-equilibrium active components with passive polymeric inclusions to produce unique material properties. To explore these composite systems, idealized models - such as polymers in active fluids - are essential to develop a predictive theoretical framework. We simulate a single, freely jointed passive chain in two-dimensional active turbulence. Active flows advect the polymer, producing a substantially enhanced diffusivity. Our results reveal that the dimensionless diffusivity obeys scaling laws governed by the P\textbackslash{}'eclet, Weissenberg, and Ericksen numbers, which paves the way for designing active/polymeric hybrid materials with predictable properties that differ significantly from those of nondeformable inclusions. ",

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N2 - Biological systems commonly combine intrinsically out-of-equilibrium active components with passive polymeric inclusions to produce unique material properties. To explore these composite systems, idealized models - such as polymers in active fluids - are essential to develop a predictive theoretical framework. We simulate a single, freely jointed passive chain in two-dimensional active turbulence. Active flows advect the polymer, producing a substantially enhanced diffusivity. Our results reveal that the dimensionless diffusivity obeys scaling laws governed by the P\'eclet, Weissenberg, and Ericksen numbers, which paves the way for designing active/polymeric hybrid materials with predictable properties that differ significantly from those of nondeformable inclusions.

AB - Biological systems commonly combine intrinsically out-of-equilibrium active components with passive polymeric inclusions to produce unique material properties. To explore these composite systems, idealized models - such as polymers in active fluids - are essential to develop a predictive theoretical framework. We simulate a single, freely jointed passive chain in two-dimensional active turbulence. Active flows advect the polymer, producing a substantially enhanced diffusivity. Our results reveal that the dimensionless diffusivity obeys scaling laws governed by the P\'eclet, Weissenberg, and Ericksen numbers, which paves the way for designing active/polymeric hybrid materials with predictable properties that differ significantly from those of nondeformable inclusions.

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Scaling laws for passive polymer dynamics in active turbulence

Abstract

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[LC]2: 'Living' Colloidal Liquid Crystals

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