1,615 research outputs found
One-dimensional Kac model of dense amorphous hard spheres
We introduce a new model of hard spheres under confinement for the study of
the glass and jamming transitions. The model is an one-dimensional chain of the
-dimensional boxes each of which contains the same number of hard spheres,
and the particles in the boxes of the ends of the chain are quenched at their
equilibrium positions. We focus on the infinite dimensional limit () of the model and analytically compute the glass transition densities
using the replica liquid theory. From the chain length dependence of the
transition densities, we extract the characteristic length scales at the glass
transition. The divergence of the lengths are characterized by the two
exponents, for the dynamical transition and for the ideal glass
transition, which are consistent with those of the -spin mean-field spin
glass model. We also show that the model is useful for the study of the growing
length scale at the jamming transition.Comment: 6 pages, 4 figure
Cluster and reentrant anomalies of nearly Gaussian core particles
We study through integral equation theory and numerical simulations the
structure and dynamics of fluids composed of ultrasoft, nearly Gaussian
particles. Namely, we explore the fluid phase diagram of a model in which
particles interact via the generalized exponential potential u(r)=\epsilon
exp[-(r/\sigma)^n], with a softness exponent n slightly larger than 2. In
addition to the well-known anomaly associated to reentrant melting, the
structure and dynamics of the fluid display two additional anomalies, which are
visible in the isothermal variation of the structure factor and diffusivity.
These features are correlated to the appearance of dimers in the fluid phase
and to the subsequent modification of the cluster structure upon compression.
We corroborate these results through an analysis of the local minima of the
potential energy surface, in which clusters appear as much tighter
conglomerates of particles. We find that reentrant melting and clustering
coexist for softness exponents ranging from 2^+ up to values relevant for the
description of amphiphilic dendrimers, i.e., n=3.Comment: 10 pages, 8 figure
Thinning or thickening? Multiple rheological regimes in dense suspensions of soft particles
The shear rheology of dense colloidal and granular suspensions is strongly
nonlinear, as these materials exhibit shear-thinning and shear-thickening,
depending on multiple physical parameters. We numerically study the rheology of
a simple model of soft repulsive particles at large densities, and show that
nonlinear flow curves reminiscent of experiments on real suspensions can be
obtained. By using dimensional analysis and basic elements of kinetic theory,
we rationalize these multiple rheological regimes and disentangle the relative
impact of thermal fluctuations, glass and jamming transitions, inertia and
particle softness on the flow curves. We characterize more specifically the
shear-thickening regime and show that both particle softness and the emergence
of a yield stress at the jamming transition compete with the inertial effects
responsible for the observed thickening behaviour. This allows us to construct
a dynamic state diagram, which can be used to analyze experiments.Comment: 6 pages, 3 figure
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