Formation of Topological Bigels in Mixtures of Colloidal Rings and Polymers

Andrea Bonato; Davide Marenduzzo; Enzo Orlandini

doi:10.1103/PhysRevLett.134.188203

Formation of Topological Bigels in Mixtures of Colloidal Rings and Polymers

Andrea Bonato, Davide Marenduzzo, Enzo Orlandini

School of Physics and Astronomy

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

Abstract

We study a spherically confined mixture of polymers and colloidal rings. Unlike in standard colloid-polymer mixtures, the polymers interact topologically with the rings by threading them. We find that, above a critical value of the ring radius, threading yields a topological transition from a fluid to a gel-like phase characterized by a space-spanning network of interlocked polymers and rings, which we refer to as a bicomponent gel, or bigel. By exploiting the mixture dual character (rings and polymers), we predict analytically the value of the critical radius. We also show that the mobility of entanglements in the mixture slows down upon entering the gel phase, due to topological hindrance arising from threadings, while the transition rates between topological states of the colloidal probes provide another strong dynamical signature of the gel phase.

Original language	English
Article number	188203
Pages (from-to)	1-6
Number of pages	6
Journal	Physical Review Letters
Volume	134
Issue number	18
DOIs	https://doi.org/10.1103/PhysRevLett.134.188203
Publication status	Published - 9 May 2025

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abstract = "We study a spherically confined mixture of polymers and colloidal rings. Unlike in standard colloid-polymer mixtures, the polymers interact topologically with the rings by threading them. We find that, above a critical value of the ring radius, threading yields a topological transition from a fluid to a gel-like phase characterized by a space-spanning network of interlocked polymers and rings, which we refer to as a bicomponent gel, or bigel. By exploiting the mixture dual character (rings and polymers), we predict analytically the value of the critical radius. We also show that the mobility of entanglements in the mixture slows down upon entering the gel phase, due to topological hindrance arising from threadings, while the transition rates between topological states of the colloidal probes provide another strong dynamical signature of the gel phase.",

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AB - We study a spherically confined mixture of polymers and colloidal rings. Unlike in standard colloid-polymer mixtures, the polymers interact topologically with the rings by threading them. We find that, above a critical value of the ring radius, threading yields a topological transition from a fluid to a gel-like phase characterized by a space-spanning network of interlocked polymers and rings, which we refer to as a bicomponent gel, or bigel. By exploiting the mixture dual character (rings and polymers), we predict analytically the value of the critical radius. We also show that the mobility of entanglements in the mixture slows down upon entering the gel phase, due to topological hindrance arising from threadings, while the transition rates between topological states of the colloidal probes provide another strong dynamical signature of the gel phase.

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Formation of Topological Bigels in Mixtures of Colloidal Rings and Polymers

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