Journal of Geophysical Research: Space Physics, ISSN 2169-9380, 05/2015, Volume 120, Issue 5, pp. 3684 - 3701

We present the ion distribution functions in the ion foreshock upstream of the terrestrial bow shock obtained with Vlasiator, a new hybrid‐Vlasov simulation...

magnetosphere | ion distributions | hybrid‐Vlasov | ion foreshock | simulations | Hybrid-Vlasov | Simulations | Ion foreshock | Magnetosphere | Ion distributions | hybrid-Vlasov | GYRATING IONS | ULF WAVES | LOW-FREQUENCY WAVES | TERRESTRIAL FORESHOCK | FIELD-ALIGNED BEAM | MAGNETOSHEATH | ASTRONOMY & ASTROPHYSICS | COLLISIONLESS BOW SHOCKS | UPSTREAM SOLAR-WIND | PERPENDICULAR COLLISIONLESS | MACROSTRUCTURE | Earth | Earth magnetosphere | Beams (radiation) | Computer simulation | Simulation | Upstream | Mathematical models | Density | Ion distribution

magnetosphere | ion distributions | hybrid‐Vlasov | ion foreshock | simulations | Hybrid-Vlasov | Simulations | Ion foreshock | Magnetosphere | Ion distributions | hybrid-Vlasov | GYRATING IONS | ULF WAVES | LOW-FREQUENCY WAVES | TERRESTRIAL FORESHOCK | FIELD-ALIGNED BEAM | MAGNETOSHEATH | ASTRONOMY & ASTROPHYSICS | COLLISIONLESS BOW SHOCKS | UPSTREAM SOLAR-WIND | PERPENDICULAR COLLISIONLESS | MACROSTRUCTURE | Earth | Earth magnetosphere | Beams (radiation) | Computer simulation | Simulation | Upstream | Mathematical models | Density | Ion distribution

Journal Article

Journal of Geophysical Research: Space Physics, ISSN 2169-9380, 03/2017, Volume 122, Issue 3, pp. 2877 - 2888

We present results from a first study of the local reconnection rate and reconnection site motion in a 2D‐3V global magnetospheric self‐consistent...

magnetopause | magnetosheath | hybrid‐Vlasov | magnetic reconnection | numerical modeling | hybrid-Vlasov | THEMIS OBSERVATIONS | MIRROR STRUCTURES | FLUX-TRANSFER EVENTS | DAYSIDE MAGNETOPAUSE | CLUSTER OBSERVATIONS | MODEL | EARTHS MAGNETOPAUSE | INTERPLANETARY MAGNETIC-FIELD | PLASMA-FLOW | ASTRONOMY & ASTROPHYSICS | Interplanetary magnetic field | Magnetic reconnection | Fluctuations | Computer simulation | Magnetosheath | Magnetopause | Flux | Magnetic islands | Magnetospheres | Steady state | Asymmetry | Simulation | Mathematical analysis | Correlation analysis | Representations | Magnetic fields | Solar wind | Islands | Flux transfer events | Magnetic properties | Mathematical models

magnetopause | magnetosheath | hybrid‐Vlasov | magnetic reconnection | numerical modeling | hybrid-Vlasov | THEMIS OBSERVATIONS | MIRROR STRUCTURES | FLUX-TRANSFER EVENTS | DAYSIDE MAGNETOPAUSE | CLUSTER OBSERVATIONS | MODEL | EARTHS MAGNETOPAUSE | INTERPLANETARY MAGNETIC-FIELD | PLASMA-FLOW | ASTRONOMY & ASTROPHYSICS | Interplanetary magnetic field | Magnetic reconnection | Fluctuations | Computer simulation | Magnetosheath | Magnetopause | Flux | Magnetic islands | Magnetospheres | Steady state | Asymmetry | Simulation | Mathematical analysis | Correlation analysis | Representations | Magnetic fields | Solar wind | Islands | Flux transfer events | Magnetic properties | Mathematical models

Journal Article

Journal of Computational Physics, ISSN 0021-9991, 05/2016, Volume 313, pp. 511 - 531

•A new hybrid kinetic electron model for electrostatic full-f gyrokinetic simulations.•The model keeps ITG-TEM turbulence, neoclassical transport, particle...

Neoclassical transport | Full-f model | Gyrokinetics | Kinetic electrons | Ion temperature gradient mode | Trapped electron mode | VLASOV SIMULATION | PLASMAS | PHYSICS, MATHEMATICAL | FLOW | TOKAMAKS | TRANSPORT | CODE | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | SYSTEMS | TURBULENCE | Nuclear energy | Turbulence | Models | Analysis | Electrons | Electric fields | Turbulent flow | Computational fluid dynamics | Computer simulation | Ion temperature | Fluid flow | Poisson equation

Neoclassical transport | Full-f model | Gyrokinetics | Kinetic electrons | Ion temperature gradient mode | Trapped electron mode | VLASOV SIMULATION | PLASMAS | PHYSICS, MATHEMATICAL | FLOW | TOKAMAKS | TRANSPORT | CODE | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | SYSTEMS | TURBULENCE | Nuclear energy | Turbulence | Models | Analysis | Electrons | Electric fields | Turbulent flow | Computational fluid dynamics | Computer simulation | Ion temperature | Fluid flow | Poisson equation

Journal Article

Computer Physics Communications, ISSN 0010-4655, 09/2018, Volume 230, pp. 121 - 134

A parallelized implementation of the Vlasov-Hybrid method (Nunn, 1993) is presented. This method is a hybrid between a gridded Eulerian description and...

Vlasov-hybrid | Particle mesh | Collisionless plasma | Electrostatic | PLASMA MODEL | PHASE-SPACE | TREE-CODE | PHYSICS, MATHEMATICAL | SCHEME | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | INTEGRATION | PARTICLE SIMULATION | MULTI-FLUID | OSCILLATIONS | NUMERICAL-SIMULATION | EQUATION

Vlasov-hybrid | Particle mesh | Collisionless plasma | Electrostatic | PLASMA MODEL | PHASE-SPACE | TREE-CODE | PHYSICS, MATHEMATICAL | SCHEME | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | INTEGRATION | PARTICLE SIMULATION | MULTI-FLUID | OSCILLATIONS | NUMERICAL-SIMULATION | EQUATION

Journal Article

5.
Full Text
Reconnection and small-scale fields in 2D-3V hybrid-kinetic driven turbulence simulations

New Journal of Physics, ISSN 1367-2630, 02/2017, Volume 19, Issue 2, p. 25007

The understanding of the fundamental properties of turbulence in collisionless plasmas, such as the solar wind, is a frontier problem in plasma physics. In...

Vlasov simulations | space plasmas | magnetic reconnection | plasma turbulence | VLASOV | DISSIPATION | PHYSICS, MULTIDISCIPLINARY | CURRENT SHEETS | CASCADES | ALFVEN WAVES | GENERATION | ALIGNED CURRENTS | SOLAR-WIND TURBULENCE

Vlasov simulations | space plasmas | magnetic reconnection | plasma turbulence | VLASOV | DISSIPATION | PHYSICS, MULTIDISCIPLINARY | CURRENT SHEETS | CASCADES | ALFVEN WAVES | GENERATION | ALIGNED CURRENTS | SOLAR-WIND TURBULENCE

Journal Article

Journal of Computational Physics, ISSN 0021-9991, 2007, Volume 225, Issue 1, pp. 753 - 770

We present a numerical scheme for the integration of the Vlasov–Maxwell system of equations for a non-relativistic plasma, in the hybrid approximation, where...

Splitting | Alfvén waves | EMHD | Hybrid | CAM | Vlasov | Parametric instability | splitting | Alfven waves | SYSTEM | parametric instability | PHYSICS, MATHEMATICAL | SCHEME | NUMERICAL-SOLUTION | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | hybrid | vlasov | INTEGRATION | EQUATION | Models | Algorithms | Analysis | Methods | Volcanology | Earth Sciences | Sciences of the Universe | PHASE SPACE | MATHEMATICAL EVOLUTION | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | APPROXIMATIONS | ELECTRONS | RELATIVISTIC PLASMA | BOLTZMANN-VLASOV EQUATION | ALGORITHMS | SUPERCOMPUTERS | ANALYTICAL SOLUTION | COMPUTERIZED SIMULATION | ELECTRIC FIELDS | DISTRIBUTION FUNCTIONS | ALFVEN WAVES | MOMENT OF INERTIA | PARAMETRIC INSTABILITIES

Splitting | Alfvén waves | EMHD | Hybrid | CAM | Vlasov | Parametric instability | splitting | Alfven waves | SYSTEM | parametric instability | PHYSICS, MATHEMATICAL | SCHEME | NUMERICAL-SOLUTION | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | hybrid | vlasov | INTEGRATION | EQUATION | Models | Algorithms | Analysis | Methods | Volcanology | Earth Sciences | Sciences of the Universe | PHASE SPACE | MATHEMATICAL EVOLUTION | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | APPROXIMATIONS | ELECTRONS | RELATIVISTIC PLASMA | BOLTZMANN-VLASOV EQUATION | ALGORITHMS | SUPERCOMPUTERS | ANALYTICAL SOLUTION | COMPUTERIZED SIMULATION | ELECTRIC FIELDS | DISTRIBUTION FUNCTIONS | ALFVEN WAVES | MOMENT OF INERTIA | PARAMETRIC INSTABILITIES

Journal Article

7.
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Vlasiator: First global hybrid-Vlasov simulations of Earth's foreshock and magnetosheath

Journal of Atmospheric and Solar-Terrestrial Physics, ISSN 1364-6826, 12/2014, Volume 120, Issue 1, pp. 24 - 35

We present results from a new hybrid-Vlasov simulation code, Vlasiator, designed for global magnetospheric simulations. Vlasiator represents ions by a...

Hybrid-Vlasov | Space plasma | Simulation | Magnetosphere | ULF WAVES | UPSTREAM | COLLISIONLESS BOW SHOCKS | GEOCHEMISTRY & GEOPHYSICS | ION DISTRIBUTIONS | METEOROLOGY & ATMOSPHERIC SCIENCES | HYPERBOLIC CONSERVATION-LAWS | MHD SIMULATION | PROPAGATION | SCHEMES | MACROSTRUCTURE | Geomagnetism | Analysis

Hybrid-Vlasov | Space plasma | Simulation | Magnetosphere | ULF WAVES | UPSTREAM | COLLISIONLESS BOW SHOCKS | GEOCHEMISTRY & GEOPHYSICS | ION DISTRIBUTIONS | METEOROLOGY & ATMOSPHERIC SCIENCES | HYPERBOLIC CONSERVATION-LAWS | MHD SIMULATION | PROPAGATION | SCHEMES | MACROSTRUCTURE | Geomagnetism | Analysis

Journal Article

Physics of Plasmas, ISSN 1070-664X, 06/2016, Volume 23, Issue 6

An electromagnetic particle simulation model has been formulated and verified for nonlinear processes of lower hybrid (LH) waves in fusion plasmas. Electron...

FLUIDS | DISPERSIONS | DISTURBANCES | PARTICLES | ELECTRONS | BOLTZMANN-VLASOV EQUATION | IONS | CONTINUITY EQUATIONS | POTENTIALS | COMPUTERIZED SIMULATION | LOWER HYBRID HEATING | LOWER HYBRID CURRENT DRIVE | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | NONLINEAR PROBLEMS | PERTURBATION THEORY | KINETIC EQUATIONS | VECTORS | DISPERSION RELATIONS | GEOMETRY

FLUIDS | DISPERSIONS | DISTURBANCES | PARTICLES | ELECTRONS | BOLTZMANN-VLASOV EQUATION | IONS | CONTINUITY EQUATIONS | POTENTIALS | COMPUTERIZED SIMULATION | LOWER HYBRID HEATING | LOWER HYBRID CURRENT DRIVE | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | NONLINEAR PROBLEMS | PERTURBATION THEORY | KINETIC EQUATIONS | VECTORS | DISPERSION RELATIONS | GEOMETRY

Journal Article

Physics of Plasmas, ISSN 1070-664X, 06/2016, Volume 23, Issue 6

An electromagnetic particle simulation model has been formulated and verified for nonlinear processes of lower hybrid (LH) waves in fusion plasmas. Electron...

Compressibility | Kinetic equations | Simulation | Computer simulation | Continuity equation | Ion dynamics | Momentum | Mathematical models | Plasmas | Vlasov equations | Particle in cell technique | Importance sampling

Compressibility | Kinetic equations | Simulation | Computer simulation | Continuity equation | Ion dynamics | Momentum | Mathematical models | Plasmas | Vlasov equations | Particle in cell technique | Importance sampling

Journal Article

Physics of Plasmas, ISSN 1070-664X, 11/2013, Volume 20, Issue 11, p. 112114

Vlasiator is a new hybrid-Vlasov plasma simulation code aimed at simulating the entire magnetosphere of the Earth. The code treats ions (protons) kinetically...

PHYSICS, FLUIDS & PLASMAS | PLASMA | SIMULATIONS | Earth magnetosphere | Ohm's Law | Magnetohydrodynamics | Computational fluid dynamics | Computer simulation | Geophysics | Plasmas | Dispersion curve analysis | Plasma waves | Wave dispersion | Fluid flow | Mathematical models | Dispersions | Magnetospheres | PHASE SPACE | OHM LAW | PLASMA SIMULATION | ELECTRONS | MATHEMATICAL MODELS | BERNSTEIN MODE | BOLTZMANN-VLASOV EQUATION | MAGNETOHYDRODYNAMICS | COMPARATIVE EVALUATIONS | ANISOTROPY | PLASMA WAVES | PROTONS | COMPUTERIZED SIMULATION | MATHEMATICAL SOLUTIONS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | W CODES | POLARIZATION | Naturvetenskap | Natural Sciences

PHYSICS, FLUIDS & PLASMAS | PLASMA | SIMULATIONS | Earth magnetosphere | Ohm's Law | Magnetohydrodynamics | Computational fluid dynamics | Computer simulation | Geophysics | Plasmas | Dispersion curve analysis | Plasma waves | Wave dispersion | Fluid flow | Mathematical models | Dispersions | Magnetospheres | PHASE SPACE | OHM LAW | PLASMA SIMULATION | ELECTRONS | MATHEMATICAL MODELS | BERNSTEIN MODE | BOLTZMANN-VLASOV EQUATION | MAGNETOHYDRODYNAMICS | COMPARATIVE EVALUATIONS | ANISOTROPY | PLASMA WAVES | PROTONS | COMPUTERIZED SIMULATION | MATHEMATICAL SOLUTIONS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | W CODES | POLARIZATION | Naturvetenskap | Natural Sciences

Journal Article

Computer Physics Communications, ISSN 0010-4655, 2011, Volume 182, Issue 12, pp. 2508 - 2518

We present some useful extensions of the spectral Fourier–Vlasov algorithm for simulations of interactions of collisionless plasmas with ion beams. For many...

Vlasov simulation | Spectral methods | Ion beams | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | PLASMA | ION-BEAM INSTABILITIES | PHYSICS, MATHEMATICAL | MAXWELL SYSTEM | Algorithms | Particle beams | Populations | Computer simulation | Portable document format | Mathematical models | Plasma heating | Distribution functions

Vlasov simulation | Spectral methods | Ion beams | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | PLASMA | ION-BEAM INSTABILITIES | PHYSICS, MATHEMATICAL | MAXWELL SYSTEM | Algorithms | Particle beams | Populations | Computer simulation | Portable document format | Mathematical models | Plasma heating | Distribution functions

Journal Article

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Reconnection and small-scale fields in 2D-3V hybrid-kinetic driven turbulence simulations

NEW JOURNAL OF PHYSICS, ISSN 1367-2630, 02/2017, Volume 19

The understanding of the fundamental properties of turbulence in collisionless plasmas, such as the solar wind, is a frontier problem in plasma physics. In...

VLASOV | DISSIPATION | FLUID SIMULATIONS | PHYSICS, MULTIDISCIPLINARY | magnetic reconnection | CURRENT SHEETS | CASCADES | MODEL | space plasmas | Vlasov simulations | SPECTRUM | plasma turbulence | SOLAR-WIND TURBULENCE

VLASOV | DISSIPATION | FLUID SIMULATIONS | PHYSICS, MULTIDISCIPLINARY | magnetic reconnection | CURRENT SHEETS | CASCADES | MODEL | space plasmas | Vlasov simulations | SPECTRUM | plasma turbulence | SOLAR-WIND TURBULENCE

Journal Article

Journal of Geophysical Research - Space Physics, ISSN 0148-0227, 11/2003, Volume 108, Issue A11, pp. 1401 - n/a

The magnetotail current layer is thought to be subject to a variety of instabilities. One instability arising from the presence of two ion populations, the...

Magnetospheric Physics | Space Plasma Physics | Magnetotail | Numerical simulation studies | Plasma waves and instabilities | magnetotail instabilities | Vlasov theory | kinetic simulations | Kelvin‐Helmholtz instability | kink mode | Kelvin-helmholtz instability | Kink mode | Magnetotail instabilities | Kinetic simulations | Kelvin-Helmholtz instability | STABILITY | MAGNETIC RECONNECTION | GEOCHEMISTRY & GEOPHYSICS | GEOSCIENCES, MULTIDISCIPLINARY | ASTRONOMY & ASTROPHYSICS | OCEANOGRAPHY | TAIL | CLUSTER | METEOROLOGY & ATMOSPHERIC SCIENCES | THIN CURRENT SHEETS

Magnetospheric Physics | Space Plasma Physics | Magnetotail | Numerical simulation studies | Plasma waves and instabilities | magnetotail instabilities | Vlasov theory | kinetic simulations | Kelvin‐Helmholtz instability | kink mode | Kelvin-helmholtz instability | Kink mode | Magnetotail instabilities | Kinetic simulations | Kelvin-Helmholtz instability | STABILITY | MAGNETIC RECONNECTION | GEOCHEMISTRY & GEOPHYSICS | GEOSCIENCES, MULTIDISCIPLINARY | ASTRONOMY & ASTROPHYSICS | OCEANOGRAPHY | TAIL | CLUSTER | METEOROLOGY & ATMOSPHERIC SCIENCES | THIN CURRENT SHEETS

Journal Article

Plasma Physics and Controlled Fusion, ISSN 0741-3335, 08/2015, Volume 57, Issue 9, pp. 95010 - 7

Nonlinear decay of a localized perturbation into ion-acoustic solitons in the presence of both trapped and super-thermal electrons (Abbasi et al 2008 Plasma...

modified Korteweg-de Vries | super-thermal electrons | hybrid (Vlasov-fluid) simulation | ion-acoustic soliton chain | PARTICLES | PHYSICS, FLUIDS & PLASMAS | PHYSICS, NUCLEAR | NONLINEAR SCHRODINGER-EQUATION | III RADIO-BURSTS | RADIATION | BEAM | DISTRIBUTIONS | ACCELERATION | DISPERSION FUNCTION | GENERATION | FREQUENCY SINUSOIDAL WAVE | Pictures | Electron velocity distribution | Controlled fusion | Solitons | Monitors | Chains | Nonlinearity | Plasmas

modified Korteweg-de Vries | super-thermal electrons | hybrid (Vlasov-fluid) simulation | ion-acoustic soliton chain | PARTICLES | PHYSICS, FLUIDS & PLASMAS | PHYSICS, NUCLEAR | NONLINEAR SCHRODINGER-EQUATION | III RADIO-BURSTS | RADIATION | BEAM | DISTRIBUTIONS | ACCELERATION | DISPERSION FUNCTION | GENERATION | FREQUENCY SINUSOIDAL WAVE | Pictures | Electron velocity distribution | Controlled fusion | Solitons | Monitors | Chains | Nonlinearity | Plasmas

Journal Article

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Simulations of ionospheric turbulence produced by HF heating near the upper hybrid layer

Radio Science, ISSN 0048-6604, 06/2016, Volume 51, Issue 6, pp. 704 - 717

Heating of the ionosphere by high‐frequency (HF), ordinary (O) mode electromagnetic waves can excite magnetic field‐aligned density striations, associated with...

Turbulence | Simulation | Electron Heating | Ionosphere | Vlasov | MODEL | TELECOMMUNICATIONS | GROUND-BASED OBSERVATIONS | GEOCHEMISTRY & GEOPHYSICS | WAVES | REMOTE SENSING | PLASMA | ASTRONOMY & ASTROPHYSICS | IRREGULARITIES | METEOROLOGY & ATMOSPHERIC SCIENCES | HIGH-LATITUDE IONOSPHERE | Physics | Turbulent flow | Bernstein waves | Electromagnetic radiation | Velocity | Heating | Electromagnetic waves | Striations | Magnetic fields | Electron energy | Electrons | Fluid dynamics | Thresholds | Fluid flow | Stochasticity

Turbulence | Simulation | Electron Heating | Ionosphere | Vlasov | MODEL | TELECOMMUNICATIONS | GROUND-BASED OBSERVATIONS | GEOCHEMISTRY & GEOPHYSICS | WAVES | REMOTE SENSING | PLASMA | ASTRONOMY & ASTROPHYSICS | IRREGULARITIES | METEOROLOGY & ATMOSPHERIC SCIENCES | HIGH-LATITUDE IONOSPHERE | Physics | Turbulent flow | Bernstein waves | Electromagnetic radiation | Velocity | Heating | Electromagnetic waves | Striations | Magnetic fields | Electron energy | Electrons | Fluid dynamics | Thresholds | Fluid flow | Stochasticity

Journal Article

Physics of Plasmas, ISSN 1070-664X, 08/2015, Volume 22, Issue 8

The present paper is devoted to simulation of nonlinear disintegration of a localized perturbation into ion-acoustic solitons train in a plasma with hot...

Electron velocity distribution | Amplitudes | Computer simulation | Disintegration | Acoustics | Plasma (physics) | Perturbation methods | Hot electrons | Evolution | Mathematical models | Vlasov equations | Solitary waves | Distribution functions

Electron velocity distribution | Amplitudes | Computer simulation | Disintegration | Acoustics | Plasma (physics) | Perturbation methods | Hot electrons | Evolution | Mathematical models | Vlasov equations | Solitary waves | Distribution functions

Journal Article

Physics of Plasmas, ISSN 1070-664X, 08/2015, Volume 22, Issue 8, p. 82108

The present paper is devoted to simulation of nonlinear disintegration of a localized perturbation into ion-acoustic solitons train in a plasma with hot...

WARM PLASMA | DENSITY | WAVES | PHYSICS, FLUIDS & PLASMAS | NONTHERMAL ELECTRONS | HOLES | NEGATIVE-IONS | PROPAGATION | DUSTY PLASMA | DISTRIBUTION FUNCTIONS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | DISTURBANCES | PLASMA | SOLITONS | ELECTRONS | BOLTZMANN-VLASOV EQUATION | IONS | ION ACOUSTIC WAVES | AMPLITUDES | KORTEWEG-DE VRIES EQUATION | COMPUTERIZED SIMULATION

WARM PLASMA | DENSITY | WAVES | PHYSICS, FLUIDS & PLASMAS | NONTHERMAL ELECTRONS | HOLES | NEGATIVE-IONS | PROPAGATION | DUSTY PLASMA | DISTRIBUTION FUNCTIONS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | DISTURBANCES | PLASMA | SOLITONS | ELECTRONS | BOLTZMANN-VLASOV EQUATION | IONS | ION ACOUSTIC WAVES | AMPLITUDES | KORTEWEG-DE VRIES EQUATION | COMPUTERIZED SIMULATION

Journal Article

Journal of Computational Physics, ISSN 0021-9991, 03/2016, Volume 309, Issue C, pp. 18 - 36

In this work we propose a Hybrid method with Deviational Particles (HDP) for a plasma modeled by the inhomogeneous Vlasov–Poisson–Landau system. We split the...

Monte Carlo methods | Plasma physics | Hybrid methods | Vlasov–Poisson–Landau system | Macro–micro projection | Deviational particles | Vlasov-Poisson-Landau system | Macro-micro projection | ALGORITHMS | SIMULATION | PHYSICS, MATHEMATICAL | MONTE-CARLO | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | BOLTZMANN-EQUATION | COULOMB COLLISIONS | NUMERICAL SCHEMES | Monte Carlo method | Analysis | Methods | Fluids | Computational fluid dynamics | Computer simulation | Fluid flow | Evolution | Mathematical models | Deviation | Plasma (physics)

Monte Carlo methods | Plasma physics | Hybrid methods | Vlasov–Poisson–Landau system | Macro–micro projection | Deviational particles | Vlasov-Poisson-Landau system | Macro-micro projection | ALGORITHMS | SIMULATION | PHYSICS, MATHEMATICAL | MONTE-CARLO | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | BOLTZMANN-EQUATION | COULOMB COLLISIONS | NUMERICAL SCHEMES | Monte Carlo method | Analysis | Methods | Fluids | Computational fluid dynamics | Computer simulation | Fluid flow | Evolution | Mathematical models | Deviation | Plasma (physics)

Journal Article

Computer Physics Communications, ISSN 0010-4655, 09/2012, Volume 183, Issue 9, pp. 1986 - 1992

A hybrid method of semi-Lagrangian and additive semi-implicit Runge–Kutta schemes is developed for gyrokinetic Vlasov simulations in a flux tube geometry. The...

Vlasov simulation | Gyrokinetics | Semi-Lagrangian scheme | Operator splitting method | Additive semi-implicit Runge–Kutta scheme | Additive semi-implicit Runge-Kutta scheme | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | INTEGRATION | CONSTRUCTION | VELOCITY-SPACE | PHYSICS, MATHEMATICAL | TEMPERATURE-GRADIENT TURBULENCE

Vlasov simulation | Gyrokinetics | Semi-Lagrangian scheme | Operator splitting method | Additive semi-implicit Runge–Kutta scheme | Additive semi-implicit Runge-Kutta scheme | COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS | INTEGRATION | CONSTRUCTION | VELOCITY-SPACE | PHYSICS, MATHEMATICAL | TEMPERATURE-GRADIENT TURBULENCE

Journal Article

Physics of Plasmas, ISSN 1070-664X, 05/2016, Volume 23, Issue 5, p. 59901

Journal Article

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