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Flow-to-fracture transition and pattern formation in a discontinuous shear thickening fluid

Deren Ozturk, Miles Morgan, Bjornar Sandnes Orcid Logo

Communications Physics, Volume: 3, Issue: 1

Swansea University Authors: Deren Ozturk, Miles Morgan, Bjornar Sandnes Orcid Logo

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DOI (Published version): 10.1038/s42005-020-0382-7

Abstract

Recent theoretical and experimental work suggests a frictionless-frictional transition with increasing inter-particle pressure explains the extreme solid-like response of discontinuous shear thickening suspensions. However, analysis of macroscopic discontinuous shear thickening flow in geometries ot...

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Published in: Communications Physics
ISSN: 2399-3650
Published: Springer Science and Business Media LLC 2020
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URI: https://cronfa.swan.ac.uk/Record/cronfa54268
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first_indexed 2020-05-18T19:08:46Z
last_indexed 2023-01-11T14:32:13Z
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spelling 2022-12-05T13:28:16.0635807 v2 54268 2020-05-18 Flow-to-fracture transition and pattern formation in a discontinuous shear thickening fluid 14712812fc31e03fc3a3bc9033165beb Deren Ozturk Deren Ozturk true false 74c1257d35ba8de6402ca451aab305a1 Miles Morgan Miles Morgan true false 61c7c04b5c804d9402caf4881e85234b 0000-0002-4854-5857 Bjornar Sandnes Bjornar Sandnes true false 2020-05-18 FGSEN Recent theoretical and experimental work suggests a frictionless-frictional transition with increasing inter-particle pressure explains the extreme solid-like response of discontinuous shear thickening suspensions. However, analysis of macroscopic discontinuous shear thickening flow in geometries other than the standard rheometry tools remain scarce. Here we use a Hele-Shaw cell geometry to visualise gas-driven invasion patterns in discontinuous shear thickening cornstarch suspensions. We plot quantitative results from pattern analysis in a volume fraction-pressure phase diagram and explain them in context of rheological measurements. We observe three distinct pattern morphologies: viscous fingering, dendritic fracturing, and system-wide fracturing, which correspond to the same packing fraction ranges as weak shear thickening, discontinuous shear thickening, and shear-jammed regimes. Journal Article Communications Physics 3 1 Springer Science and Business Media LLC 2399-3650 3 7 2020 2020-07-03 10.1038/s42005-020-0382-7 COLLEGE NANME Science and Engineering - Faculty COLLEGE CODE FGSEN Swansea University UKRI, EP/S034587/1 2022-12-05T13:28:16.0635807 2020-05-18T13:58:12.4182515 Faculty of Science and Engineering School of Engineering and Applied Sciences - Chemical Engineering Deren Ozturk 1 Miles Morgan 2 Bjornar Sandnes 0000-0002-4854-5857 3 54268__17670__ad328dba3281438e8a283d086a1be1d9.pdf 54268.pdf 2020-07-07T14:44:04.1855599 Output 1709702 application/pdf Version of Record true Released under the terms of a Creative Commons Attribution 4.0 International License (CC-BY). true eng http://creativecommons.org/licenses/by/4.0/
title Flow-to-fracture transition and pattern formation in a discontinuous shear thickening fluid
spellingShingle Flow-to-fracture transition and pattern formation in a discontinuous shear thickening fluid
Deren Ozturk
Miles Morgan
Bjornar Sandnes
title_short Flow-to-fracture transition and pattern formation in a discontinuous shear thickening fluid
title_full Flow-to-fracture transition and pattern formation in a discontinuous shear thickening fluid
title_fullStr Flow-to-fracture transition and pattern formation in a discontinuous shear thickening fluid
title_full_unstemmed Flow-to-fracture transition and pattern formation in a discontinuous shear thickening fluid
title_sort Flow-to-fracture transition and pattern formation in a discontinuous shear thickening fluid
author_id_str_mv 14712812fc31e03fc3a3bc9033165beb
74c1257d35ba8de6402ca451aab305a1
61c7c04b5c804d9402caf4881e85234b
author_id_fullname_str_mv 14712812fc31e03fc3a3bc9033165beb_***_Deren Ozturk
74c1257d35ba8de6402ca451aab305a1_***_Miles Morgan
61c7c04b5c804d9402caf4881e85234b_***_Bjornar Sandnes
author Deren Ozturk
Miles Morgan
Bjornar Sandnes
author2 Deren Ozturk
Miles Morgan
Bjornar Sandnes
format Journal article
container_title Communications Physics
container_volume 3
container_issue 1
publishDate 2020
institution Swansea University
issn 2399-3650
doi_str_mv 10.1038/s42005-020-0382-7
publisher Springer Science and Business Media LLC
college_str Faculty of Science and Engineering
hierarchytype
hierarchy_top_id facultyofscienceandengineering
hierarchy_top_title Faculty of Science and Engineering
hierarchy_parent_id facultyofscienceandengineering
hierarchy_parent_title Faculty of Science and Engineering
department_str School of Engineering and Applied Sciences - Chemical Engineering{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Engineering and Applied Sciences - Chemical Engineering
document_store_str 1
active_str 0
description Recent theoretical and experimental work suggests a frictionless-frictional transition with increasing inter-particle pressure explains the extreme solid-like response of discontinuous shear thickening suspensions. However, analysis of macroscopic discontinuous shear thickening flow in geometries other than the standard rheometry tools remain scarce. Here we use a Hele-Shaw cell geometry to visualise gas-driven invasion patterns in discontinuous shear thickening cornstarch suspensions. We plot quantitative results from pattern analysis in a volume fraction-pressure phase diagram and explain them in context of rheological measurements. We observe three distinct pattern morphologies: viscous fingering, dendritic fracturing, and system-wide fracturing, which correspond to the same packing fraction ranges as weak shear thickening, discontinuous shear thickening, and shear-jammed regimes.
published_date 2020-07-03T04:07:41Z
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score 11.035655

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