76 research outputs found
Hydrodynamics within the Electric Double Layer on slipping surfaces
We show, using extensive Molecular Dynamics simulations, that the dynamics of
the electric double layer (EDL) is very much dependent on the wettability of
the charged surface on which the EDL develops. For a wetting surface, the
dynamics, characterized by the so-called Zeta potential, is mainly controlled
by the electric properties of the surface, and our work provides a clear
interpretation for the traditionally introduced immobile Stern layer. In
contrast, the immobile layer disappears for non-wetting surfaces and the Zeta
potential deduced from electrokinetic effects is considerably amplified by the
existence of a slippage at the solid substrate.Comment: accepted for publication in Physical Review Letter
Large permeabilities of hourglass nanopores: From hydrodynamics to single file transport
In fluid transport across nanopores, there is a fundamental dissipation that
arises from the connection between the pore and the macroscopic reservoirs.
This entrance effect can hinder the whole transport in certain situations, for
short pores and/or highly slipping channels. In this paper, we explore the
hydrodynamic permeability of hourglass shape nanopores using molecular dynamics
(MD) simulations, with the central pore size ranging from several nanometers
down to a few Angstr{\"o}ms. Surprisingly, we find a very good agreement
between MD results and continuum hydrodynamic predictions, even for the
smallest systems undergoing single file transport of water. An optimum of
permeability is found for an opening angle around 5 degree, in agreement with
continuum predictions, yielding a permeability five times larger than for a
straight nanotube. Moreover, we find that the permeability of hourglass shape
nanopores is even larger than single nanopores pierced in a molecular thin
graphene sheet. This suggests that designing the geometry of nanopores may help
considerably increasing the macroscopic permeability of membranes
Beating the teapot effect
We investigate the dripping of liquids around solid surfaces in the regime of
inertial flows, a situation commonly encountered with the so-called "teapot
effect". We demonstrate that surface wettability is an unexpected key factor in
controlling flow separation and dripping, the latter being completely
suppressed in the limit of superhydrophobic substrates. This unforeseen
coupling is rationalized in terms of a novel hydro-capillary adhesion
framework, which couples inertial flows to surface wettability effects. This
description of flow separation successfully captures the observed dependence on
the various experimental parameters - wettability, flow velocity, solid surface
edge curvature-. As a further illustration of this coupling, a real-time
control of dripping is demonstrated using electro-wetting for contact angle
actuation.Comment: 4 pages; movies at http://lpmcn.univ-lyon1.fr/~lbocque
Flow-Induced Shift of the Donnan Equilibrium for Ultra-Sensitive Mass Transport Measurement Through a Single Nanochannel
Despite mass flow is arguably the most elementary transport associated to nanofluidics, its measurement still constitutes a significant bottleneck for the development of this promising field. Here, we investigate how a liquid flow perturbs the ubiquitous enrichment-or depletion-of a solute inside a single nanochannel. Using Fluorescence Correlation Spectroscopy to access the local solute concentration, we demonstrate that the initial enrichment-the so-called Donnan equilibrium-is depleted under flow thus revealing the underlying mass transport. Combining theoretical and numerical calculations beyond the classical 1D treatments of nanochannels, we rationalize quantitatively our observations and demonstrate unprecedented flow rate sensitivity. Because the present mass transport investigations are based on generic effects, we believe they can develop into a versatile approach for nanofluidics
Destabilization of a flow focused suspension of magnetotactic bacteria
Active matter is a new class of material, intrinsically out-of equilibrium
with intriguing properties. So far, the recent upsurge of studies has mostly
focused on the spontaneous behavior of these systems --in the absence of
external constraints or driving--. Yet, many real life systems evolve under
constraints, being both submitted to flow and various taxis. In the present
work, we demonstrate a new experimental system which opens up the way for
quantitative investigations, and discriminating examinations, of the
challenging theoretical description of such systems. We explore the behavior of
magnetotactic bacteria as a particularly rich and versatile class of driven
matter, which behavior can be studied under contrasting and contradicting
stimuli. In particular we demonstrate that the competing driving of an
orienting magnetic field and hydrodynamic flow lead not only to jetting, but
also unveils a new pearling instability. This illustrates new structuring
capabilities of driven active matter
Sedimentation of self-propelled Janus colloids: polarization and pressure
We study experimentally-using Janus colloids-and theoretically-using Active
Brownian Particles- the sedimentation of dilute active colloids. We first
confirm the existence of an exponential density profile. We show experimentally
the emergence of a polarized steady state outside the effective equilibrium
regime, i.e. when v_s is not much smaller than the propulsion speed. The
experimental distribution of polarization is very well described by the
theoretical prediction with no fitting parameter. We then discuss and compare
three different definitions of pressure for sedimenting particles: the weight
of particles above a given height, the flux of momentum and active impulse, and
the force density measured by pressure gauges
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