Search results for "Euler equations"

showing 10 items of 35 documents

A stabilized finite element method for particulate two-phase flow equations laminar isothermal flow

1997

A finite element method for the solution of particulate two-phase flows is presented. The governing system has the form of compressible Navier-Stokes equations with unknown pressure. Therefore, the proposed method must capture the main features of stabilized methods used for incompressible as well as for compressible Navier-Stokes equations. Solution of the resulting nonlinear algebraic system of equations is based on the linearization using Newton method in conjunction with Generalized Minimal Residual iterative solver and Incomplete LU preconditioning. The method has been tested for three test cases including venturi tube flow, flow over backward step and mixing of flows in t-junction.

Mechanical EngineeringIsothermal flowComputational MechanicsGeneral Physics and AstronomyLaminar flowMechanicsCompressible flowFinite element methodComputer Science ApplicationsEuler equationsPhysics::Fluid Dynamicssymbols.namesakeClassical mechanicsMechanics of MaterialsPressure-correction methodsymbolsNavier–Stokes equationsMathematicsExtended finite element methodComputer Methods in Applied Mechanics and Engineering
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Inertial modes in stratified rotating neutron stars : An evolutionary description

2005

With (non-barotropic) equations of state valid even when the neutron, proton and electron content of neutron star cores is not in beta equilibrium, we study inertial and composition gravity modes of relativistic rotating neutron stars. We solve the relativistic Euler equations in the time domain with a three dimensional numerical code based on spectral methods, in the slow rotation, relativistic Cowling and anelastic approximations. Principally, after a short description of the gravity modes due to smooth composition gradients, we focus our analysis on the question of how the inertial modes are affected by non-barotropicity of the nuclear matter. In our study, the deviation with respect to …

Nuclear and High Energy PhysicsInertial frame of referenceFOS: Physical sciencesGeneral Relativity and Quantum Cosmology (gr-qc)Astrophysics7. Clean energy01 natural sciencesGeneral Relativity and Quantum CosmologyGravitation[PHYS.ASTR.CO]Physics [physics]/Astrophysics [astro-ph]/Cosmology and Extra-Galactic Astrophysics [astro-ph.CO]symbols.namesake0103 physical sciencesNeutron010303 astronomy & astrophysicsPhysics[PHYS.GRQC] Physics [physics]/General Relativity and Quantum Cosmology [gr-qc]010308 nuclear & particles physicsAstrophysics (astro-ph)Nuclear matterRelativistic Euler equationsComputational physicsEuler equationsNumerical relativityNeutron starClassical mechanics[PHYS.ASTR.CO] Physics [physics]/Astrophysics [astro-ph]/Cosmology and Extra-Galactic Astrophysics [astro-ph.CO]symbols[PHYS.GRQC]Physics [physics]/General Relativity and Quantum Cosmology [gr-qc]
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Numerical approximation of the viscous quantum hydrodynamic model for semiconductors

2006

The viscous quantum hydrodynamic equations for semiconductors with constant temperature are numerically studied. The model consists of the one-dimensional Euler equations for the electron density and current density, including a quantum correction and viscous terms, coupled to the Poisson equation for the electrostatic potential. The equations can be derived formally from a Wigner-Fokker-Planck model by a moment method. Two different numerical techniques are used: a hyperbolic relaxation scheme and a central finite-difference method. By simulating a ballistic diode and a resonant tunneling diode, it is shown that numerical or physical viscosity changes significantly the behavior of the solu…

Numerical AnalysisApplied MathematicsNumerical analysisFinite difference methodResonant-tunneling diodeFinite differenceRelaxation (iterative method)Euler equationsComputational Mathematicssymbols.namesakeClassical mechanicsQuantum hydrodynamicssymbolsPoisson's equationMathematicsApplied Numerical Mathematics
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Power ENO methods: a fifth-order accurate Weighted Power ENO method

2004

In this paper we introduce a new class of ENO reconstruction procedures, the Power ENO methods, to design high-order accurate shock capturing methods for hyperbolic conservation laws, based on an extended class of limiters, improving the behavior near discontinuities with respect to the classical ENO methods. Power ENO methods are defined as a correction of classical ENO methods [J. Comput. Phys. 71 (1987) 231], by applying the new limiters on second-order differences or higher. The new class of limiters includes as a particular case the minmod limiter and the harmonic limiter used for the design of the PHM methods [see SIAM J. Sci. Comput. 15 (1994) 892]. The main features of these new ENO…

Numerical AnalysisConservation lawPhysics and Astronomy (miscellaneous)Applied MathematicsMathematical analysisScalar (physics)Harmonic (mathematics)Computer Science ApplicationsEuler equationsMaxima and minimaComputational Mathematicssymbols.namesakeDiscontinuity (linguistics)Riemann problemModeling and SimulationShock capturing methodsymbolsMathematicsJournal of Computational Physics
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Asymptotic preserving IMEX finite volume schemes for low Mach number Euler equations with gravitation

2017

In this paper we will present and analyze a new class of the IMEX finite volume schemes for the Euler equations with a gravity source term. We will in particular concentrate on a singular limit of weakly compressible flows when the Mach number M1. In order to efficiently resolve slow dynamics we split the whole nonlinear system in a stiff linear part governing the acoustic and gravity waves and a non-stiff nonlinear part that models nonlinear advection effects. For time discretization we use a special class of the so-called globally stiffly accurate IMEX schemes and approximate the stiff linear operator implicitly and the non-stiff nonlinear operator explicitly. For spatial discretization t…

Numerical AnalysisFinite volume methodPhysics and Astronomy (miscellaneous)DiscretizationApplied MathematicsMathematical analysis010103 numerical & computational mathematics01 natural sciencesComputer Science ApplicationsEuler equations010101 applied mathematicsLinear mapComputational Mathematicssymbols.namesakeNonlinear systemMach numberModeling and SimulationStability theorysymbolsCompressibility0101 mathematicsMathematicsJournal of Computational Physics
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Comparison between adaptive and uniform discontinuous Galerkin simulations in dry 2D bubble experiments

2013

Accepted by the Journal of Computational Physics Adaptive mesh refinement generally aims to increase computational efficiency without compromising the accuracy of the numerical solution. However it is an open question in which regions the spatial resolution can actually be coarsened without affecting the accuracy of the result. This question is investigated for a specific example of dry atmospheric convection, namely the simulation of warm air bubbles. For this purpose a novel numerical model is developed that is tailored towards this specific application. The compressible Euler equations are solved with a Discontinuous Galerkin method. Time integration is done with an IMEXmethod and the dy…

Numerical AnalysisMathematical optimizationPhysics and Astronomy (miscellaneous)Mathematical modelAdaptive mesh refinementApplied MathematicsNumerical analysisAdaptive Mesh RefinementCompressible flowComputer Science ApplicationsEuler equationsDry Warm Air BubbleComputational Mathematicssymbols.namesakeMeteorologyIMEXDiscontinuous Galerkin methodModeling and SimulationDiscontinuous GalerkinsymbolsApplied mathematicsGalerkin methodNavier–Stokes equationsMathematicsJournal of Computational Physics
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Existence and uniqueness for the Prandtl equations

2001

International audience; Under the hypothesis of analyticity of the data with respect to the tangential variable we prove the existence and uniqueness of the mild solution of Prandtl boundary layer equation. This can be considered an improvement of the results of [8] as we do not require analyticity with respect to the normal variable. (C) 2001 Academie des sciences/Editions scientifiques et medicales Elsevier SAS.

Partial differential equation010102 general mathematicsPrandtl numberMathematical analysisGeneral Medicine01 natural sciencesEuler equations010101 applied mathematicssymbols.namesakeBoundary layer[MATH.MATH-MP]Mathematics [math]/Mathematical Physics [math-ph]symbolsUniqueness0101 mathematicsConvection–diffusion equationNavier–Stokes equationsVariable (mathematics)Mathematics
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Removability of a Level Set for Solutions of Quasilinear Equations

2005

In this paper, we study the removability of a level set for the solutions of quasilinear elliptic and parabolic equations of the second order. We show, under rather general assumptions on the coeff...

Partial differential equationDifferential equationIndependent equationApplied MathematicsMathematical analysisMathematics::Analysis of PDEsParabolic partial differential equationEuler equationssymbols.namesakeMethod of characteristicsElliptic partial differential equationsymbolsHyperbolic partial differential equationAnalysisMathematicsCommunications in Partial Differential Equations
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The relaxation-time limit in the quantum hydrodynamic equations for semiconductors

2006

Abstract The relaxation-time limit from the quantum hydrodynamic model to the quantum drift–diffusion equations in R 3 is shown for solutions which are small perturbations of the steady state. The quantum hydrodynamic equations consist of the isentropic Euler equations for the particle density and current density including the quantum Bohm potential and a momentum relaxation term. The momentum equation is highly nonlinear and contains a dispersive term with third-order derivatives. The equations are self-consistently coupled to the Poisson equation for the electrostatic potential. The relaxation-time limit is performed both in the stationary and the transient model. The main assumptions are…

PhysicsIndependent equationApplied MathematicsGlobal relaxation-time limitQuantum hydrodynamic equationsEuler equationsMomentumNonlinear systemsymbols.namesakeClassical mechanicsThird-order derivativesMaster equationQuantum drift–diffusion equationssymbolsMethod of quantum characteristicsPoisson's equationQuantum dissipationAnalysisJournal of Differential Equations
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IMEX Finite Volume Methods for Cloud Simulation

2017

We present new implicit-explicit (IMEX) finite volume schemes for numerical simulation of cloud dynamics. We use weakly compressible equations to describe fluid dynamics and a system of advection-diffusion-reaction equations to model cloud dynamics. In order to efficiently resolve slow dynamics we split the whole nonlinear system in a stiff linear part governing the acoustic and gravitational waves as well as diffusive effects and a non-stiff nonlinear part that models nonlinear advection effects. We use a stiffly accurate second order IMEX scheme for time discretization to approximate the stiff linear operator implicitly and the non-stiff nonlinear operator explicitly. Fast microscale clou…

PhysicsNonlinear systemsymbols.namesakeFinite volume methodComputer simulationDiscretizationCompressibilityFluid dynamicssymbolsApplied mathematicsNavier–Stokes equationsEuler equations
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