Search results for "Bolt"

showing 10 items of 180 documents

On the full Boltzmann equations for leptogenesis

2009

We consider the full Boltzmann equations for standard and soft leptogenesis, instead of the usual integrated Boltzmann equations which assume kinetic equilibrium for all species. Decays and inverse decays may be inefficient for thermalising the heavy-(s)neutrino distribution function, leading to significant deviations from kinetic equilibrium. We analyse the impact of using the full kinetic equations in the case of a previously generated lepton asymmetry, and find that the washout of this initial asymmetry due to the interactions of the right-handed neutrino is larger than when calculated via the integrated equations. We also solve the full Boltzmann equations for soft leptogenesis, where t…

PhysicsleptogenesisParticle physicsmedia_common.quotation_subjectHigh Energy Physics::PhenomenologyFOS: Physical sciencesInverseFísicaAstronomy and AstrophysicsKinetic energyAsymmetrysymbols.namesakeHigh Energy Physics - PhenomenologyHigh Energy Physics - Phenomenology (hep-ph)Distribution functionneutrino theoryLeptogenesisBoltzmann constantsymbolsphysics of the early universeHigh Energy Physics::ExperimentNeutrinomedia_commonLepton
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Heat transfer in conducting and radiating bodies

1997

Abstract We introduce briefly some nonlocal models for heat transfer in conducting and radiating media. The goal is to give an idea of the general mathematical structure and related existence results for such models.

Physicssymbols.namesakeClassical mechanicsStefan–Boltzmann lawThermal radiationNonlocal problemsApplied MathematicsHeat transfersymbolsStefan-Boltzmann lawStatistical physicsMathematical structureHeat radiationApplied Mathematics Letters
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A Second Order Accurate Kinetic Relaxation Scheme for Inviscid Compressible Flows

2013

In this paper we present a kinetic relaxation scheme for the Euler equations of gas dynamics in one space dimension. The method is easily applicable to solve any complex system of conservation laws. The numerical scheme is based on a relaxation approximation for conservation laws viewed as a discrete velocity model of the Boltzmann equation of kinetic theory. The discrete kinetic equation is solved by a splitting method consisting of a convection phase and a collision phase. The convection phase involves only the solution of linear transport equations and the collision phase instantaneously relaxes the distribution function to an equilibrium distribution. We prove that the first order accur…

Physicssymbols.namesakeConservation lawDistribution functionInviscid flowEntropy (statistical thermodynamics)Mathematical analysissymbolsKinetic schemeRelaxation (approximation)Boltzmann equationEuler equations
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On the existence of kinetic equations

1974

The existence of the Boltzmann equation and its generalizations is studied by analysing the order of magnitude of their terms. As a consequence we conclude that the reduced distribution functions are not analytic in the density.

Physicssymbols.namesakeDifferential equationLattice Boltzmann methodssymbolsStatistical mechanicsPoisson–Boltzmann equationPlasma modelingBoltzmann equationMaxwell–Boltzmann distributionBoltzmann distributionMathematical physicsIl Nuovo Cimento B Series 11
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Exact results for the homogeneous cooling state of an inelastic hard-sphere gas

1998

The infinite set of moments of the two-particle distribution function is found exactly for the uniform cooling state of a hard-sphere gas with inelastic collisions. Their form shows that velocity correlations cannot be neglected, and consequently the 'molecular chaos' hypothesis leading to the inelastic Boltzmann and Enskog kinetic equations must be questioned. © 1998 Cambridge University Press.

Physicssymbols.namesakeInfinite setClassical mechanicsDistribution functionBoltzmann constantsymbolsInelastic collisionMolecular chaosHard spheresInelastic scatteringCondensed Matter PhysicsBoltzmann equationJournal of Plasma Physics
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Electrokinetic Phenomena Revisited: A Lattice—Boltzmann Approach

2003

The Lattice-Boltzmann method (LBM) is an efficient tool to solve the Navier-Stokes equations. Based on this method we have developed a scheme to investigate electrokinetic phenomena in charged colloidal suspensions. The equations of motion that are solved are the so-called electrokinetic equations, i.e. a set of partial differential equations that couple the gradient of the electrostatic potential to the hydrodynamic flow by means of a mean field theory. These equations have been extensively used to study electroviscous phenomena for the limit of a weakly charged sphere in an unbounded electrolyte. We demonstrate that our method can be applied beyond these limit. As an example we discuss th…

Physics::Fluid DynamicsElectrokinetic phenomenaPartial differential equationClassical mechanicsMean field theorySedimentation (water treatment)Lattice Boltzmann methodsEquations of motionSPHERESLimit (mathematics)Mathematics
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Solving the heat-flow problem with transient relativistic fluid dynamics

2014

Israel-Stewart theory is a causal, stable formulation of relativistic dissipative fluid dynamics. This theory has been shown to give a decent description of the dynamical behavior of a relativistic fluid in cases where shear stress becomes important. In principle, it should also be applicable to situations where heat flow becomes important. However, it has been shown that there are cases where Israel-Stewart theory cannot reproduce phenomena associated with heat flow. In this paper, we derive a relativistic dissipative fluid-dynamical theory from kinetic theory which provides a good description of all dissipative phenomena, including heat flow. We explicitly demonstrate this by comparing th…

Physics::Fluid DynamicsPhysicsNuclear and High Energy Physicsta114Quark–gluon plasmaDynamics (mechanics)Fluid dynamicsKinetic theory of gasesDissipative systemShear stressMechanicsTransient (oscillation)Boltzmann equationPhysical Review D
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X-ray computed tomography and numerical analysis of water-saturated porous materials

2012

A method for imaging a water-saturated porous material is developed in order to simulate a fluid flow through it using the Lattice Boltzmann method. The value of its flow permeability is compared to the value for the same sample when it is dry. An explanation for the difference in the experimental values of permeability for air and water is sought. A reference is given by experimental values from flow measurements that are interpreted according to Darcy's law of permeability.

Physics::Fluid Dynamicshuokoisuustomografiax-ray computed tomographyröntgentutkimusläpäisevyyspermeabilityDarcy's lawfysiikkaporous materialsPhysics::Atmospheric and Oceanic PhysicsPhysics::Geophysicsthe Lattice Boltzmann method
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Fluid flow simulations meet high-speed video : Computer vision comparison of droplet dynamics

2018

Hypothesis While multiphase flows, particularly droplet dynamics, are ordinary in nature as well as in industrial processes, their mathematical and computational modelling continue to pose challenging research tasks - patent approaches for tackling them are yet to be found. The lack of analytical flow field solutions for non-trivial droplet dynamics hinders validation of computer simulations and, hence, their application in research problems. High-speed videos and computer vision algorithms can provide a viable approach to validate simulations directly against experiments. Experiments Droplets of water (or glycerol-water mixtures) impacting on both hydrophobic and superhydrophobic surfaces …

Physics::Fluid Dynamicsvideokuvausexperimentalhigh-speed videokokeet (tutkimustoiminta)droplethydrodynamiikkakonenäkösimulointihydrophobicLattice Boltzmannpisarat
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Iterative integral equation methods for structural coarse-graining

2021

In this paper, new Newton and Gauss-Newton methods for iterative coarse-graining based on integral equation theory are evaluated and extended. In these methods, the potential update is calculated from the current and target radial distribution function, similar to iterative Boltzmann inversion, but gives a potential update of quality comparable with inverse Monte Carlo. This works well for the coarse-graining of molecules to single beads, which we demonstrate for water. We also extend the methods to systems that include coarse-grained bonded interactions and examine their convergence behavior. Finally, using the Gauss-Newton method with constraints, we derive a model for single bead methano…

Quantitative Biology::BiomoleculesMonte Carlo methodGeneral Physics and AstronomyInverseRadial distribution functionIntegral equationInversion (discrete mathematics)symbols.namesakeBoltzmann constantConvergence (routing)symbolsApplied mathematicsGranularityPhysical and Theoretical ChemistryMathematicsThe Journal of Chemical Physics
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