878 research outputs found
Steady self-diffusion in classical gases
A steady self-diffusion process in a gas of hard spheres at equilibrium is
analyzed. The system exhibits a constant gradient of labeled particles. Neither
the concentration of these particles nor its gradient are assumed to be small.
It is shown that the Boltzmann-Enskog kinetic equation has an exact solution
describing the state. The hydrodynamic transport equation for the density of
labeled particles is derived, with an explicit expression for the involved
self-diffusion transport coefficient. Also an approximated expression for the
one-particle distribution function is obtained. The system does not exhibit any
kind of rheological effects. The theoretical predictions are compared with
numerical simulations using the direct simulation Monte Carlo method and a
quite good agreement is found
Uniform self-diffusion in a granular gas
A granular gas composed of inelastic hard spheres or disks in the homogeneous
cooling state is considered. Some of the particles are labeled and their number
density exhibits a time-independent linear profile along a given direction. As
a consequence, there is a uniform flux of labeled particles in that direction.
It is shown that the inelastic Boltzmann-Enskog kinetic equation has a solution
describing this self-diffusion state. Approximate expressions for the transport
equation and the distribution function of labeled particles are derived. The
theoretical predictions are compared with simulation results obtained using the
direct Monte Carlo method to generate solutions of the kinetic equation. A
fairly good agreement is found
Vibrated granular gas confined by a piston
The steady state of a vibrated granular gas confined by a movable piston on
the top is discussed. Particular attention is given to the hydrodynamic
boundary conditions to be used when solving the inelastic Navier-Stokes
equations. The relevance of an exact general condition relating the grain
fluxes approaching and moving away from each of the walls is emphasized. It is
shown how it can be used to get a consistent hydrodynamic description of the
boundaries. The obtained expressions for the fields do not contain any
undetermined parameter. Comparison of the theoretical predictions with
molecular dynamics simulation results is carried out, and a good agreement is
observed for low density and not too large inelasticity. A practical way of
introducing small finite density corrections to the dilute limit theory is
proposed, to improve the accuracy of the theory
The shearing instability of a dilute granular mixture
The shearing instability of a dilute granular mixture composed of smooth
inelastic hard spheres or disks is investigated. By using the Navier-Stokes
hydrodynamic equations, it is shown that the scaled transversal velocity mode
exhibits a divergent behaviour, similarly to what happens in one-component
systems. The theoretical prediction for the critical size is compared with
direct Monte Carlo simulations of the Boltzmann equations describing the
system, and a good agreement is found. The total energy fluctuations in the
vicinity of the transition are shown to scale with the second moment of the
distribution. The scaling distribution function is the same as found in other
equilibrium and non-equilibrium phase transitions, suggesting the existence of
some kind of universality
Power-law decay of the velocity autocorrelation function of a granular fluid in the homogeneous cooling state
The hydrodynamic part of the velocity autocorrelation function of a granular
fluid in the homogeneous cooling state has been calculated by using
mode-coupling theory for a finite system with periodic boundary conditions. The
existence of the shearing instability, leading to a divergent behavior of the
velocity flow fluctuations, is taken into account. A time region in which the
velocity autocorrelation function exhibits a power law decay, when time is
measured by the number of collisions per particle, has been been identified.
Also the explicit form of the exponential asymptotic long time decay has been
obtained. The theoretical prediction for the power law decay is compared with
molecular dynamics simulation results, and a good agreement is found, after
taking into account finite size corrections. The effects of approaching the
shearing instability are also explored
Energy partition and segregation for an intruder in a vibrated granular system under gravity
The difference of temperatures between an impurity and the surrounding gas in
an open vibrated granular system is studied. It is shown that, in spite of the
high inhomogeneity of the state, the temperature ratio remains constant in the
bulk of the system. The lack of energy equipartition is associated to the
change of sign of the pressure diffusion coefficient for the impurity at
certain values of the parameters of the system, leading to a segregation
criterium. The theoretical predictions are consistent with previous
experimental results, and also in agreement with molecular dynamics simulation
results reported in this paper.Comment: To appear in Phys. Rev. Let
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