1,477 research outputs found
Quasi-2D dynamic jamming in cornstarch suspensions: visualization and force measurements
We report experiments investigating jamming fronts in a floating layer of
cornstarch suspension. The suspension has a packing fraction close to jamming,
which dynamically turns into a solid when impacted at a high speed. We show
that the front propagates in both axial and transverse direction from the point
of impact, with a constant ratio between the two directions of propagation of
approximately 2. Inside the jammed solid, we observe an additional compression,
which results from the increasing stress as the solid grows. During the initial
growth of the jammed solid, we measure a force response that can be completely
accounted for by added mass. Only once the jamming front reaches a boundary,
the added mass cannot account for the measured force anymore. We do not,
however, immediately see a strong force response as we would expect when
compressing a jammed packing. Instead, we observe a delay in the force response
on the pusher, which corresponds to the time it takes for the system to develop
a close to uniform velocity gradient that spans the complete system.Comment: 7 pages, 7 figure
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 behavior. Based on
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.Comment: 9 pages, 3 figure
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