60 research outputs found
On the possibility of extending the Nore-Frenkel generalized law of correspondent states to non-isotropic patchy interactions
Colloidal systems (and protein solutions) are often characterized by
attractive interactions whose range is much smaller than the particle size.
When this is the case and the interaction is spherical, systems obey a
generalized law of correspondent states (GLCS), first proposed by Noro and
Frenkel [ J.Chem.Phys. 113, 2941 (2000) ]. The thermodynamic properties become
insensitive to the details of the potential, depending only on the value of the
second virial coefficient B_2 and the density . The GLCS does not
generically hold for the case of non-spherical potentials. In this Letter we
suggest that when particles interact via short-ranged small-angular amplitude
patchy interactions (so that the condition of only one bond per patch is
fulfilled) it is still possible to generalize the GLCS close to the liquid-gas
critical point. Keywords: Colloids, Second Virial Coefficient, Proteins
interactions, Short-ranged attractive attractions.Comment: 11 pages, 3 figures. Accepted for publication on J. Phys. Chem.
Effective forces in square well and square shoulder fluids
We derive an analytical expression for the effective force between a pair of
macrospheres immersed in a sea of microspheres, in the case where the
interaction between the two unlike species is assumed to be a square well or a
square shoulder of given range and depth (or height). This formula extends a
similar one developed in the case of hard core interactions only. Qualitative
features of such effective force and the resulting phase diagram are then
analyzed in the limit of no interaction between the small particles.
Approximate force profiles are then obtained by means of integral equation
theories (PY and HNC) combined with the superposition approximation and
compared with exact ones from direct Monte Carlo simulations.Comment: 34 page
Oscillatory athermal quasi-static deformation of a model glass
We report computer simulations of oscillatory athermal quasi-static shear
deformation of dense amorphous samples of a three dimensional model glass
former. A dynamical transition is observed as the amplitude of the deformation
is varied: for large values of the amplitude the system exhibits diffusive
behavior and loss of memory of the initial conditions, whereas localization is
observed for small amplitudes. Our results suggest that the same kind of
transition found in driven colloidal systems is present in the case of
amorphous solids (e.g. metallic glasses). The onset of the transition is shown
to be related to the onset of energy dissipation. Shear banding is observed for
large system sizes, without, however, affecting qualitative aspects of the
transition
Enhanced tunneling conductivity induced by gelation of attractive colloids
We show that the formation of a gel by conducting colloidal particles leads
to a dramatic enhancement in bulk conductivity, due to inter-particle electron
tunneling, combining predictions from molecular dynamics simulations with
structural measurements in an experimental colloid system. Our results show how
colloidal gelation can be used as a general route to huge enhancements of
conductivity, and suggest a feasible way for developing cheap materials with
novel properties and low metal content.Comment: 8 pages, 8 figures, 2 table
A hard-sphere quasicrystal stabilized by configurational entropy
Due to their aperiodic nature, quasicrystals are one of the least understood
phases in statistical physics. One significant complication they present in
comparison to their periodic counterparts is the fact that any quasicrystal can
be realized as an exponentially large number of different tilings, resulting in
a significant contribution to the quasicrystal entropy. Here, we use
free-energy calculations to demonstrate that it is this configurational entropy
which stabilizes a dodecagonal quasicrystal in a binary mixture of hard spheres
on a plane. Our calculations also allow us to quantitatively confirm that in
this system all tiling realizations are essentially equally likely, with
free-energy differences less than 0.0001 per particle -- an observation
that could be the related to the observation of only random tilings in soft
matter quasicrystals. Owing to the simplicity of the model and its available
counterparts in colloidal experiments, we believe that this system is a
excellent candidate to achieve the long-awaited quasicrystal self-assembly on
the micron scale.Comment: Contains an SI as ancillary fil
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