Extracting microscopic insight from transient dielectric measurements during large amplitude oscillatory shear

Noah H Cho; Jiachun Shi; Ryan P. Murphy; John K Riley; Simon A Rogers; Jeffrey J Richards

doi:10.1039/D3SM00786C

Extracting microscopic insight from transient dielectric measurements during large amplitude oscillatory shear

Noah H Cho, Jiachun Shi, Ryan P. Murphy, John K Riley, Simon A Rogers, Jeffrey J Richards

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

Abstract

Probing the transient microstructure of soft matter far from equilibrium is an ongoing challenge to understanding material processing. In this work, we investigate inverse worm-like micelles undergoing large amplitude oscillatory shear using time-resolved dielectric spectroscopy. By controlling the Weissenburg number, we compare the non-linear microstructure response of branched and unbranched worm-like micelles and isolate distinct elastic effects that manifest near flow reversal. We validate our dielectric measurements with small angle neutron scattering and employ sequence of physical processes to disentangle the elastic and viscous contributions of the stress.

Original language	English (US)
Pages (from-to)	9379-9388
Number of pages	10
Journal	Soft Matter
Volume	19
Issue number	48
Early online date	Aug 29 2023
DOIs	https://doi.org/10.1039/D3SM00786C
State	Published - Aug 29 2023

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10.1039/D3SM00786C

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title = "Extracting microscopic insight from transient dielectric measurements during large amplitude oscillatory shear",

abstract = "Probing the transient microstructure of soft matter far from equilibrium is an ongoing challenge to understanding material processing. In this work, we investigate inverse worm-like micelles undergoing large amplitude oscillatory shear using time-resolved dielectric spectroscopy. By controlling the Weissenburg number, we compare the non-linear microstructure response of branched and unbranched worm-like micelles and isolate distinct elastic effects that manifest near flow reversal. We validate our dielectric measurements with small angle neutron scattering and employ sequence of physical processes to disentangle the elastic and viscous contributions of the stress.",

author = "Cho, {Noah H} and Jiachun Shi and Murphy, {Ryan P.} and Riley, {John K} and Rogers, {Simon A} and Richards, {Jeffrey J}",

note = "Funding Information: The authors acknowledge support for the VSANS beamline from the Center for High Resolution Neutron Scattering (CHRNS), a national user facility jointly funded by the NCNR and the NSF under Agreement No. DMR-2010792. We appreciate numerous discussions with Steve Kline regarding the strategy of analysis of time-resolved SANS data. N. H. C. would like to recognize ACS PRF Award 60442-DNI6 for support during the completion of experimental works. JS and SAR acknowledge support from the National Science Foundation under the DMREF Awards DMR-2119172. The authors thank Steve Kline and Brian Maranville for fruitful discussions regarding event mode data processing. Commercial equipment and materials identified in this work is not intended to imply recommendation or endorsement by NIST. Publisher Copyright: {\textcopyright} 2023 The Royal Society of Chemistry.",

year = "2023",

month = aug,

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doi = "10.1039/D3SM00786C",

language = "English (US)",

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publisher = "Royal Society of Chemistry",

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T1 - Extracting microscopic insight from transient dielectric measurements during large amplitude oscillatory shear

AU - Cho, Noah H

AU - Shi, Jiachun

AU - Murphy, Ryan P.

AU - Riley, John K

AU - Rogers, Simon A

AU - Richards, Jeffrey J

N1 - Funding Information: The authors acknowledge support for the VSANS beamline from the Center for High Resolution Neutron Scattering (CHRNS), a national user facility jointly funded by the NCNR and the NSF under Agreement No. DMR-2010792. We appreciate numerous discussions with Steve Kline regarding the strategy of analysis of time-resolved SANS data. N. H. C. would like to recognize ACS PRF Award 60442-DNI6 for support during the completion of experimental works. JS and SAR acknowledge support from the National Science Foundation under the DMREF Awards DMR-2119172. The authors thank Steve Kline and Brian Maranville for fruitful discussions regarding event mode data processing. Commercial equipment and materials identified in this work is not intended to imply recommendation or endorsement by NIST. Publisher Copyright: © 2023 The Royal Society of Chemistry.

PY - 2023/8/29

Y1 - 2023/8/29

N2 - Probing the transient microstructure of soft matter far from equilibrium is an ongoing challenge to understanding material processing. In this work, we investigate inverse worm-like micelles undergoing large amplitude oscillatory shear using time-resolved dielectric spectroscopy. By controlling the Weissenburg number, we compare the non-linear microstructure response of branched and unbranched worm-like micelles and isolate distinct elastic effects that manifest near flow reversal. We validate our dielectric measurements with small angle neutron scattering and employ sequence of physical processes to disentangle the elastic and viscous contributions of the stress.

AB - Probing the transient microstructure of soft matter far from equilibrium is an ongoing challenge to understanding material processing. In this work, we investigate inverse worm-like micelles undergoing large amplitude oscillatory shear using time-resolved dielectric spectroscopy. By controlling the Weissenburg number, we compare the non-linear microstructure response of branched and unbranched worm-like micelles and isolate distinct elastic effects that manifest near flow reversal. We validate our dielectric measurements with small angle neutron scattering and employ sequence of physical processes to disentangle the elastic and viscous contributions of the stress.

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JO - Soft Matter

JF - Soft Matter

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Extracting microscopic insight from transient dielectric measurements during large amplitude oscillatory shear

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