232 research outputs found
Drop impact on a flexible fiber
When droplets impact fibrous media, the liquid can be captured by the fibers
or contact then break away. Previous studies have shown that the efficiency of
drop capture by a rigid fiber depends on the impact velocity and defined a
threshold velocity below which the drop is captured. However, it is necessary
to consider the coupling of elastic and capillary effects to achieve a greater
understanding of the capture process for soft substrates. Here, we study
experimentally the dynamics of a single drop impacting on a thin flexible
fiber. Our results demonstrate that the threshold capture velocity depends on
the flexibility of fibers in a non-monotonic way. We conclude that tuning the
mechanical properties of fibers can optimize the efficiency of droplet capture.Comment: Soft Matter (2015
Wetting of crossed fibers: multiple steady states and symmetry breaking
We investigate the wetting properties of the simplest element of an array of
random fibers: two rigid fibers crossing with an inclination angle and in
contact with a droplet of a perfectly wetting liquid. We show experimentally
that the liquid adopts different morphologies when the inclination angle is
increased: a column shape, a mixed morphology state where a drop lies at the
end of a column, or a drop centered at the node. An analytical model is
provided that predicts the wetting length as well as the presence of a
non-symmetric state in the mixed morphology regime. The model also highlights a
symmetry breaking at the transition between the column state and the mixed
morphology. The possibility to tune the morphology of the liquid could have
important implications for drying processes
Damping of liquid sloshing by foams: from everyday observations to liquid transport
We perform experiments on the sloshing dynamics of liquids in a rectangular
container submitted to an impulse. We show that when foam is placed on top of
the liquid the oscillations of the free interface are significantly damped. The
ability to reduce sloshing and associated splashing could find applications in
numerous industrial processes involving liquid transport.Comment: Accepted for publication in Journal of Visualizatio
Wetting morphologies on an array of fibers of different radii
We investigate the equilibrium morphology of a finite volume of liquid placed
on two parallel rigid fibers of different radii. As observed for identical
radii fibers, the liquid is either in a column morphology or adopts a drop
shape depending on the inter-fiber distance. However the cross-sectional area
and the critical inter-fiber distance at which the transition occurs are both
modified by the polydispersity of the fibers. Using energy considerations, we
analytically predict the critical inter-fiber distance corresponding to the
transition between the column and the drop morphologies occurs. This distance
depends both on the radii of the fibers and on the contact angle of the liquid.
We perform experiments using a perfectly wetting liquid on two parallel nylon
fibers: the results are in good agreement with our analytical model. The
morphology of the capillary bridges between fibers of different radii is
relevant to the modeling of large arrays of polydisperse fibers
Wetting morphologies on randomly oriented fibers
We characterize the different morphologies adopted by a drop of liquid placed
on two randomly oriented fibers, which is a first step toward understanding the
wetting of fibrous networks. The present work reviews previous modeling for
parallel and touching crossed fibers and extends it to an arbitrary orientation
of the fibers characterized by the tilting angle and the minimum spacing
distance. Depending on the volume of liquid, the spacing distance between
fibers and the angle between the fibers, we highlight that the liquid can adopt
three different equilibrium morphologies: (1) a column morphology in which the
liquid spreads between the fibers, (2) a mixed morphology where a drop grows at
one end of the column or (3) a single drop located at the node. We capture the
different morphologies observed using an analytical model that predicts the
equilibrium configuration of the liquid based on the geometry of the fibers and
the volume of liquid
Failure of mean-field approach in out-of-equilibrium Anderson model
To explore the limitations of the mean field approximation, frequently used
in \textit{ab initio} molecular electronics calculations, we study an
out-of-equilibrium Anderson impurity model in a scattering formalism. We find
regions in the parameter space where both magnetic and non-magnetic solutions
are stable. We also observe a hysteresis in the non-equilibrium magnetization
and current as a function of the applied bias voltage. The mean field method
also predicts incorrectly local moment formation for large biases and a spin
polarized current, and unphysical kinks appear in various physical quantities.
The mean field approximation thus fails in every region where it predicts local
moment formation.Comment: 5 pages, 5 figure
Dip-coating of suspensions
Withdrawing a plate from a suspension leads to the entrainment of a coating
layer of fluid and particles on the solid surface. In this article, we study
the Landau-Levich problem in the case of a suspension of non-Brownian particles
at moderate volume fraction . We observe different regimes
depending on the withdrawal velocity , the volume fraction of the suspension
, and the diameter of the particles . Our results exhibit three
coating regimes. (i) At small enough capillary number , no particles are
entrained, and only a liquid film coats the plate. (ii) At large capillary
number, we observe that the thickness of the entrained film of suspension is
captured by the Landau-Levich law using the effective viscosity of the
suspension . (iii) At intermediate capillary numbers, the situation
becomes more complicated with a heterogeneous coating on the substrate. We
rationalize our experimental findings by providing the domain of existence of
these three regimes as a function of the fluid and particles properties
Corrugated interfaces in multiphase core-annular flow
Microfluidic devices can be used to produce highly controlled and
monodisperse double or multiple emulsions. The presence of inner drops inside a
jet of the middle phase introduces deformations in the jet, which leads to
breakup into monodisperse double emulsions. However, the ability to generate
double emulsions can be compromised when the interfacial tension between the
middle and outer phases is low, leading to flow with high capillary and Weber
numbers. In this case, the interface between the fluids is initially deformed
by the inner drops but the jet does not break into drops. Instead, the jet
becomes highly corrugated, which prevents formation of controlled double
emulsions. We show using numerical calculations that the corrugations are
caused by the inner drops perturbing the interface and the perturbations are
then advected by the flow into complex shapes
Beam tuning and stabilization using beam phase measurement at GANIL
International audienc
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