102 research outputs found
Consistent and transferrable coarse-grained model for semidilute polymer solutions in good solvent
We present a coarse-grained model for linear polymers with a tunable number
of effective atoms (blobs) per chain interacting by intra- and inter-molecular
potentials obtained at zero density. We show how this model is able to
accurately reproduce the universal properties of the underlying solution of
athermal linear chains at various levels of coarse-graining and in a range of
chain densities which can be widened by increasing the spatial resolution of
the multiblob representation, i.e., the number of blobs per chain. The present
model is unique in its ability to quantitatively predict thermodynamic and
large scale structural properties of polymer solutions deep in the semidilute
regime with a very limited computational effort, overcoming most of the
problems related to the simulations of semidilute polymer solutions in good
solvent conditions.Comment: 19 pages, 15 figures, 3 table
Depletion effects in colloid-polymer solutions
The surface tension, the adsorption, and the depletion thickness of polymers
close to a single nonadsorbing colloidal sphere are computed by means of Monte
Carlo simulations. We consider polymers under good-solvent conditions and in
the thermal crossover region between good-solvent and behavior. In the
dilute regime we consider a wide range of values of , from (planar
surface) up to -50, while in the semidilute regime, for
( is the polymer concentration and is
its value at overlap), we only consider and 2. The results are
compared with the available theoretical predictions, verifying the existing
scaling arguments. Field-theoretical results, both in the dilute and in the
semidilute regime, are in good agreement with the numerical estimates for
polymers under good-solvent conditions.Comment: 26 pages, 12 figure
Bulk viscosity of the Lennard-Jones system at the triple point by dynamical Non Equilibrium Molecular Dynamics
Non-equilibrium Molecular Dynamics (NEMD) calculations of the bulk viscosity
of the triple point Lennard-Jones fluid are performed with the aim of
investigating the origin of the observed disagreement between Green-Kubo
estimates and previous NEMD data. We show that a careful application of the
Doll's perturbation field, the dynamical NEMD method, the instantaneous form of
the perturbation and the "subtraction technique" provides a NEMD estimate of
the bulk viscosity at zero field in full agreement with the value obtained by
the Green-Kubo formula. As previously reported for the shear viscosity, we find
that the bulk viscosity exhibits a large linear regime with the field intensity
which confirms the Lennard-Jones fluid as a genuine Newtonian fluid even at
triple point.Comment: 27 pages, 11 figure
Coarse-graining polymer solutions: a critical appraisal of single- and multi-site models
We critically discuss and review the general ideas behind single- and
multi-site coarse-grained (CG) models as applied to macromolecular solutions in
the dilute and semi-dilute regime. We first consider single-site models with
zero-density and density-dependent pair potentials. We highlight advantages and
limitations of each option in reproducing the thermodynamic behavior and the
large-scale structure of the underlying reference model. As a case study we
consider solutions of linear homopolymers in a solvent of variable quality.
Secondly, we extend the discussion to multi-component systems presenting, as a
test case, results for mixtures of colloids and polymers. Specifically, we
found the CG model with zero-density potentials to be unable to predict
fluid-fluid demixing in a reasonable range of densities for mixtures of
colloids and polymers of equal size. For larger colloids, the polymer volume
fractions at which phase separation occurs are largely overestimated. CG models
with density-dependent potentials are somewhat less accurate than models with
zero-density potentials in reproducing the thermodynamics of the system and,
although they presents a phase separation, they significantly underestimate the
polymer volume fractions along the binodal. Finally, we discuss a general
multi-site strategy, which is thermodynamically consistent and fully
transferable with the number of sites, and that allows us to overcome most of
the limitations discussed for single-site models.Comment: 23 pages, 9 figures, 4 table
Integral-equation analysis of single-site coarse-grained models for polymer-colloid mixtures
We discuss the reliability of integral-equation methods based on several
commonly used closure relations in determining the phase diagram of
coarse-grained models of soft-matter systems characterized by mutually
interacting soft and hard-core particles. Specifically, we consider a set of
potentials appropriate to describe a system of hard-sphere colloids and linear
homopolymers in good solvent, and investigate the behavior when the soft
particles are smaller than the colloids, which is the regime of validity of the
coarse-grained models. Using computer-simulation results as a benchmark, we
find that the hypernetted-chain approximation provides accurate estimates of
thermodynamics and structure in the colloid-gas phase in which the density of
colloids is small. On the other hand, all closures considered appear to be
unable to describe the behavior of the mixture in the colloid-liquid phase, as
they cease to converge at polymer densities significantly smaller than those at
the binodal. As a consequence, integral equations appear to be unable to
predict a quantitatively correct phase diagram.Comment: 16 pages, 11 figures, 3 table
Single chain elasticity and thermoelasticity of polyethylene
Single-chain elasticity of polyethylene at point up to 90% of
stretching with respect to its contour length is computed by Monte-Carlo
simulation of an atomistic model in continuous space. The elasticity law
together with the free-energy and the internal energy variations with
stretching are found to be very well represented by the wormlike chain model up
to 65% of the chain elongation, provided the persistence length is treated as a
temperature dependent parameter. Beyond this value of elongation simple ideal
chain models are not able to describe the Monte Carlo data in a thermodynamic
consistent way. This study reinforces the use of the wormlike chain model to
interpret experimental data on the elasticity of synthetic polymers in the
finite extensibility regime, provided the chain is not yet in its fully
stretched regime. Specific solvent effects on the elasticity law and the
partition between energetic and entropic contributions to single chain
elasticity are investigated.Comment: 32 pages with 5 figures included. Accepted as a regular paper on The
Journal of Chemical Physics, August 2002. This article may be downloaded for
personal use only. Any other use requires prior permission of the author and
the American Institute of Physic
Equation of state of metallic hydrogen from Coupled Electron-Ion Monte Carlo simulations
We present a study of hydrogen at pressures higher than molecular
dissociation using the Coupled Electron-Ion Monte Carlo method. These
calculations use the accurate Reptation Quantum Monte Carlo method to estimate
the electronic energy and pressure while doing a Monte Carlo simulation of the
protons. In addition to presenting simulation results for the equation of state
over a large region of phase space, we report the free energy obtained by
thermodynamic integration. We find very good agreement with DFT calculations
for pressures beyond 600 GPa and densities above . Both
thermodynamic as well as structural properties are accurately reproduced by DFT
calculations. This agreement gives a strong support to the different
approximations employed in DFT, specifically the approximate
exchange-correlation potential and the use of pseudopotentials for the range of
densities considered. We find disagreement with chemical models, which suggests
a reinvestigation of planetary models, previously constructed using the
Saumon-Chabrier-Van Horn equations of state.Comment: 9 pages, 7 figure
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