High-speed ultrasound imaging in dense suspensions reveals impact-activated solidification due to dynamic shear jamming
High-speed ultrasound imaging in dense suspensions reveals impact-activated solidification due to dynamic shear jamming
A remarkable property of dense suspensions is that they can transform from liquid-like at rest to solid-like under sudden impact. Previous work showed that this impact-induced solidification involves rapidly moving jamming fronts; however, details of this process have remained unresolved. Here we use high-speed ultrasound imaging to probe non-invasively how the interior of a dense suspension responds to impact. Measuring the speed of sound we demonstrate that the solidification proceeds without a detectable increase in packing fraction, and imaging the evolving flow field we find that the shear intensity is maximized right at the jamming front. Taken together, this provides direct experimental evidence for jamming by shear, rather than densification, as driving the transformation to solid-like behaviour. On the basis of these findings we propose a new model to explain the anisotropy in the propagation speed of the fronts and delineate the onset conditions for dynamic shear jamming in suspensions.
Han, Endao
5092fa24-61ad-4fd8-9942-17ae58dc6957
Peters, Ivo R.
222d846e-e620-4017-84cb-099b14ff2d75
Jaeger, Heinrich M.
ade31874-6896-4cfa-9ca3-6ac1abffc770
5 September 2016
Han, Endao
5092fa24-61ad-4fd8-9942-17ae58dc6957
Peters, Ivo R.
222d846e-e620-4017-84cb-099b14ff2d75
Jaeger, Heinrich M.
ade31874-6896-4cfa-9ca3-6ac1abffc770
Han, Endao, Peters, Ivo R. and Jaeger, Heinrich M.
(2016)
High-speed ultrasound imaging in dense suspensions reveals impact-activated solidification due to dynamic shear jamming.
Nature Communications, 7, [12243].
(doi:10.1038/ncomms12243).
Abstract
A remarkable property of dense suspensions is that they can transform from liquid-like at rest to solid-like under sudden impact. Previous work showed that this impact-induced solidification involves rapidly moving jamming fronts; however, details of this process have remained unresolved. Here we use high-speed ultrasound imaging to probe non-invasively how the interior of a dense suspension responds to impact. Measuring the speed of sound we demonstrate that the solidification proceeds without a detectable increase in packing fraction, and imaging the evolving flow field we find that the shear intensity is maximized right at the jamming front. Taken together, this provides direct experimental evidence for jamming by shear, rather than densification, as driving the transformation to solid-like behaviour. On the basis of these findings we propose a new model to explain the anisotropy in the propagation speed of the fronts and delineate the onset conditions for dynamic shear jamming in suspensions.
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High-speed ultrasound imaging in dense suspensions reveals impact-activated solidification due to dynamic shear jamming.pdf
- Accepted Manuscript
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ncomms12243.pdf
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Accepted/In Press date: 15 June 2016
e-pub ahead of print date: 20 July 2016
Published date: 5 September 2016
Organisations:
Aerodynamics & Flight Mechanics Group
Identifiers
Local EPrints ID: 399958
URI: http://eprints.soton.ac.uk/id/eprint/399958
PURE UUID: 75042020-602c-4c33-8549-d3d4d8772763
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Date deposited: 06 Sep 2016 08:55
Last modified: 15 Mar 2024 03:52
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Author:
Endao Han
Author:
Heinrich M. Jaeger
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