Mesoscopic Theory of Granular Fluids

Noije, Twan van; Ernst, M. H.; Brito, Ricardo; Orza, J.A.G.

doi:10.1103/physrevlett.79.411

Cited by 168 publications

(201 citation statements)

References 12 publications

(52 reference statements)

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“…The HCS is unstable against spatial fluctuations: this instability appears at scales larger than a critical length L c which depends on α and on the mean free path, therefore it can be avoided by taking the linear size of the system L < L c [19]. It is possible to analyze the effects of spatial fluctuations by deriving mesoscopic equations through a linearization around the HCS [35]. The resulting equations are generally coupled, but in the Fourier representation the transverse velocity field results decoupled from the other modes.…”

Section: The Homogeneous Cooling and Its Stationary Representationmentioning

confidence: 99%

“…where ν(t) is the kinematic viscosity which, in the HCS, is proportional to T g (see [4] for definitions), v th (t) ≡ 2T g /m and c is expected to be 1 [21,35,3]. The last term in the Eq.…”

Section: The Homogeneous Cooling and Its Stationary Representationmentioning

confidence: 99%

“…This question is usually more complicate than the analogous problem at equilibrium, because less symmetries are available, the most important being the invariance under time-reversal. Models of granular gases [30,29] lend themselves to be analyzed under this aspect: they are usually far from equilibrium and exhibit peculiar properties, such as: breakdown of energy equipartition [16,25,28], spontaneous symmetry breaking (vortices and clustering) [35,18], "Maxwell demon" effects [15], "ratcheting" effects [12], and lot more. At the same time granular experiments usually concern small samples, or the order of 10 3 ± 10 4 grains, and therefore extensive observables are affected by large (easily detectable) fluctuations [18].…”

Section: Introductionmentioning

confidence: 99%

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Role of Molecular Chaos in Granular Fluctuating Hydrodynamics

Costantini

Puglisi

2011

Math. Model. Nat. Phenom.

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Abstract. We perform a numerical study of the fluctuations of the rescaled hydrodynamic transverse velocity field during the cooling state of a homogeneous granular gas. We are interested in the role of Molecular Chaos for the amplitude of the hydrodynamic noise and its relaxation in time. For this purpose we compare the results of Molecular Dynamics (MD, deterministic dynamics) with those from Direct Simulation Monte Carlo (DSMC, random process), where Molecular Chaos can be directly controlled. It is seen that the large time decay of the fluctuation's autocorrelation is always dictated by the viscosity coefficient predicted by granular hydrodynamics, independently of the numerical scheme (MD or DSMC). On the other side, the noise amplitude in Molecular Dynamics, which is known to violate the equilibrium Fluctuation-Dissipation relation, is not always accurately reproduced in a DSMC scheme. The agreement between the two models improves if the probability of recollision (controlling Molecular Chaos) is reduced by increasing the number of virtual particles per cells in the DSMC. This result suggests that DSMC is not necessarily more efficient than MD, if the real number of particles is small (∼ 10 3 ± 10 4 ) and if one is interested in accurately reproduce fluctuations. An open question remains about the small-times behavior of the autocorrelation function in the DSMC, which in MD and in kinetic theory predictions is not a straight exponential.

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Section: The Homogeneous Cooling and Its Stationary Representationmentioning

confidence: 99%

Section: The Homogeneous Cooling and Its Stationary Representationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Role of Molecular Chaos in Granular Fluctuating Hydrodynamics

Costantini

Puglisi

2011

Math. Model. Nat. Phenom.

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“…In general, the collision frequency ω(T ) is proportional to the root mean square velocity v 0 = 2T /m, and its explicit form for hard sphere fluids can be found in Refs. [24,25]. When the system is prepared initially in a homogeneous equilibrium state, it evolves at short times in a spatially homogeneous cooling state (HCS) with a time dependent temperature.…”

Section: Dynamic Equations and Instabilitiesmentioning

confidence: 99%

“…The search for the proper macroscopic description of unstable granular fluids has been pursued by many authors [1][2][3][4][5][6][7][8][9][10][11][12][13]18,20,[22][23][24][25][26][27][28][29][30][31][32]. Recently, two new points of view have been presented, namely by Ben-Naim et al [11] and by Soto et al [12].…”

Section: Introductionmentioning

confidence: 99%

Untitled

Wakou

Brito

Ernst

2002

Journal of Statistical Physics

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In this paper we show how, under certain restrictions, the hydrodynamic equations for the freely evolving granular fluid fit within the framework of the time dependent Landau-Ginzburg (LG) models for critical and unstable fluids (e.g. spinodal decomposition). The granular fluid, which is usually modeled as a fluid of inelastic hard spheres (IHS), exhibits two instabilities: the spontaneous formation of vortices and of high density clusters. We suppress the clustering instability by imposing constraints on the system sizes, in order to illustrate how LG-equations can be derived for the order parameter, being the rate of deformation or shear rate tensor, which controls the formation of vortex patterns. From the shape of the energy functional we obtain the stationary patterns in the flow field.Quantitative predictions of this theory for the stationary states agree well with molecular dynamics simulations of a fluid of inelastic hard disks.

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Correlation Time and Diffusion Coefficient Imaging: Application to a Granular Flow System

Caprihan

Seymour

2000

Journal of Magnetic Resonance

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Mesoscopic Theory of Granular Fluids

Cited by 168 publications

References 12 publications

Role of Molecular Chaos in Granular Fluctuating Hydrodynamics

Role of Molecular Chaos in Granular Fluctuating Hydrodynamics

Untitled

Correlation Time and Diffusion Coefficient Imaging: Application to a Granular Flow System

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