Decoupling elasticity and electrical conductivity of carbon-black gels filled with insulating non-Brownian grains

Thomas Larsen; Jesper de C. Christiansen; John R. Royer; Fraser H.J. Laidlaw; Wilson C.K. Poon; Tom Larsen; Søren J. Andreasen

doi:10.1103/PhysRevApplied.22.034023

Decoupling elasticity and electrical conductivity of carbon-black gels filled with insulating non-Brownian grains

Thomas Larsen, Jesper de C. Christiansen, John R. Royer, Fraser H.J. Laidlaw, Wilson C.K. Poon, Tom Larsen, Søren J. Andreasen

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

A unique bistable transition has been identified in granular-colloidal gel composites, resulting from shear-induced phase separation of the gel phase into dense blobs. In energy applications, it is critical to understand how this transition influences electrical performance. Mixing conductive colloids with conductive inclusions, we find that the conductivity and elasticity move in concert, both decreasing in the collapsed phase-separated state. Surprisingly, with insulating inclusions, these properties can become decoupled, with the conductivity instead increasing despite the collapse of the gel structure.

Original language	English
Article number	034023
Journal	Physical Review Applied
Volume	22
Issue number	3
Number of pages	8
ISSN	2331-7019
DOIs	https://doi.org/10.1103/PhysRevApplied.22.034023
Publication status	Published - 10 Sept 2024

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10.1103/PhysRevApplied.22.034023

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title = "Decoupling elasticity and electrical conductivity of carbon-black gels filled with insulating non-Brownian grains",

abstract = "A unique bistable transition has been identified in granular-colloidal gel composites, resulting from shear-induced phase separation of the gel phase into dense blobs. In energy applications, it is critical to understand how this transition influences electrical performance. Mixing conductive colloids with conductive inclusions, we find that the conductivity and elasticity move in concert, both decreasing in the collapsed phase-separated state. Surprisingly, with insulating inclusions, these properties can become decoupled, with the conductivity instead increasing despite the collapse of the gel structure.",

author = "Thomas Larsen and Christiansen, {Jesper de C.} and Royer, {John R.} and Laidlaw, {Fraser H.J.} and Poon, {Wilson C.K.} and Tom Larsen and Andreasen, {S{\o}ren J.}",

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AU - Larsen, Tom

AU - Andreasen, Søren J.

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N2 - A unique bistable transition has been identified in granular-colloidal gel composites, resulting from shear-induced phase separation of the gel phase into dense blobs. In energy applications, it is critical to understand how this transition influences electrical performance. Mixing conductive colloids with conductive inclusions, we find that the conductivity and elasticity move in concert, both decreasing in the collapsed phase-separated state. Surprisingly, with insulating inclusions, these properties can become decoupled, with the conductivity instead increasing despite the collapse of the gel structure.

AB - A unique bistable transition has been identified in granular-colloidal gel composites, resulting from shear-induced phase separation of the gel phase into dense blobs. In energy applications, it is critical to understand how this transition influences electrical performance. Mixing conductive colloids with conductive inclusions, we find that the conductivity and elasticity move in concert, both decreasing in the collapsed phase-separated state. Surprisingly, with insulating inclusions, these properties can become decoupled, with the conductivity instead increasing despite the collapse of the gel structure.

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ER -

Decoupling elasticity and electrical conductivity of carbon-black gels filled with insulating non-Brownian grains

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AAU Circular Plastics

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Decoupling elasticity and electrical conductivity of carbon-black gels filled with insulating non-Brownian grains

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AAU Circular Plastics

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