2,589 research outputs found
Correlation factor for diffusion in cubic crystals with solute-vacancy interactions of arbitrary range
A formalism using a double Laplace Fourier transform of the transport
equation yields the return probabilities of the vacancy in the vicinity of the
tracer atom in the presence of solute-vacancy interactions of arbitrary
extension. Studying model cases, it is shown that taking into account the full
range of the interaction may change noticeably the correlation factor. The
latter depends tightly on the pattern of migration barriers which is chosen to
describe the vacancy jumps around the tracer atom. A thorough ab initio
evaluation of all barriers is rarely available in the literature. It is shown
that approximations often used to overcome this lack of information can be
misleading. The examination of dilute systems recently studied shows that the
interactions within the first three neighbour shells dictate the final value
with a good precision. The main improvement of the modelling comes from
dropping the restrictive assumption which impose an equal value to the jump
frequencies leading to a dissociation of the solute-vacancy pair.Comment: 45 pages; 8 figure
Flow boundary conditions from nano- to micro-scales
The development of microfluidic devices has recently revived the interest in
"old" problems associated with transport at, or across, interfaces. As the
characteristic sizes are decreased, the use of pressure gradients to transport
fluids becomes problematic, and new, interface driven, methods must be
considered. This has lead to new investigations of flow near interfaces, and to
the conception of interfaces engineered at various scales to reduce flow
friction. In this review, we discuss the present theoretical understanding of
flow past solid interfaces at different length scales. We also briefly discuss
the corresponding phenomenon of heat transport, and the influence of surface
slip on interface driven (e.g. electro-osmotic) flows.Comment: submitted to "Soft Matter
Nucleation in hydrophobic cylindrical pores : a lattice model
We consider the nucleation process associated with capillary condensation of
a vapor in a hydrophobic cylindrical pore (capillary evaporation). The
liquid-vapor transition is described within the framework of a simple lattice
model. The phase properties are characterized both at the mean-field level and
using Monte-Carlo simulations. The nucleation process for the liquid to vapor
transition is then specifically considered. Using umbrella sampling techniques,
we show that nucleation occurs through the condensation of an asymmetric vapor
bubble at the pore surface. Even for highly confined systems, good agreement is
found with macroscopic considerations based on classical nucleation theory. The
results are discussed in the context of recent experimental work on the
extrusion of water in hydrophobic pores
Tasting edge effects
We show that the baking of potato wedges constitutes a crunchy example of
edge effects, which are usually demonstrated in electrostatics. A simple model
of the diffusive transport of water vapor around the potato wedges shows that
the water vapor flux diverges at the sharp edges in analogy with its
electrostatic counterpart. This increased evaporation at the edges leads to the
crispy taste of these parts of the potatoes.Comment: to appear in American Journal of Physic
Slow Kinetics of Capillary Condensation in Confined Geometry: Experiment and Theory
When two solid surfaces are brought in contact, water vapor present in the
ambient air may condense in the region of the contact to form a liquid bridge
connecting the two surfaces : this is the so-called capillary condensation.
This phenomenon has drastic consequences on the contact between solids,
modifying the macroscopic adhesion and friction properties. In this paper, we
present a survey of the work we have performed both experimentally and
theoretically to understand the microscopic foundations of the kinetics of
capillary condensation. From the theoretical point of view, we have computed
the free energy barrier associated with the condensation of the liquid from the
gas in a confined system. These calculations allow to understand the existence
of very large hysteresis, which is often associated with capillary
condensation. This results are compatible with experimental results obtained
with a surface forces apparatus in a vapor atmosphere, showing a large hysteris
of the surface energy of two parallel planes as a function of their distance.
In the second part, we present some experiments on the influence of humidity on
the avalanche angle of granular media. We show that the ageing in time of this
avalanche angle can be explained by the slow kinetics of capillary condensation
in a random confined geometry.Comment: Special Volume of Colloids and Surfaces A,Proceedings of
Nanocapillarity: Wetting of Heterogeneous Surfaces and Porous Solids,June
25-27, 2001, TRI/Princeton International Workshop, Editor: Alexander V.
Neimar
Shear localization in a model glass
Using molecular dynamics simulations, we show that a simple model of a glassy
material exhibits the shear localization phenomenon observed in many complex
fluids. At low shear rates, the system separates into a fluidized shear-band
and an unsheared part. The two bands are characterized by a very different
dynamics probed by a local intermediate scattering function. Furthermore, a
stick-slip motion is observed at very small shear rates. Our results, which
open the possibility of exploring complex rheological behavior using
simulations, are compared to recent experiments on various soft glasses.Comment: 4 pages, 4 figures (5 figure files
Shear-induced crystallization of a dense rapid granular flow: hydrodynamics beyond the melting point?
We investigate shear-induced crystallization in a very dense flow of
mono-disperse inelastic hard spheres. We consider a steady plane Couette flow
under constant pressure and neglect gravity. We assume that the granular
density is greater than the melting point of the equilibrium phase diagram of
elastic hard spheres. We employ a Navier-Stokes hydrodynamics with constitutive
relations all of which (except the shear viscosity) diverge at the crystal
packing density, while the shear viscosity diverges at a smaller density. The
phase diagram of the steady flow is described by three parameters: an effective
Mach number, a scaled energy loss parameter, and an integer number m: the
number of half-oscillations in a mechanical analogy that appears in this
problem. In a steady shear flow the viscous heating is balanced by energy
dissipation via inelastic collisions. This balance can have different forms,
producing either a uniform shear flow or a variety of more complicated,
nonlinear density, velocity and temperature profiles. In particular, the model
predicts a variety of multi-layer two-phase steady shear flows with sharp
interphase boundaries. Such a flow may include a few zero-shear (solid-like)
layers, each of which moving as a whole, separated by fluid-like regions. As we
are dealing with a hard sphere model, the granulate is fluidized within the
"solid" layers: the granular temperature is non-zero there, and there is energy
flow through the boundaries of the "solid" layers. A linear stability analysis
of the uniform steady shear flow is performed, and a plausible bifurcation
diagram of the system, for a fixed m, is suggested. The problem of selection of
m remains open.Comment: 11 pages, 7 eps figures, to appear in PR
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