Astrophysical Journal, ISSN 0004-637X, 08/2017, Volume 844, Issue 2, p. 153

...) effect-through the action of the ponderomotive force. In open field regions, we model the dependence of fractionation on the plasma upflow velocity through the chromosphere for both shear (or planar...

waves | Sun: abundances | turbulence | Sun: chromosphere | RATE COEFFICIENTS | HELIUM ABUNDANCE | TRANSITION REGION | TORSIONAL MOTIONS | II SPICULES | ULTRAVIOLET SPECTRUM | ASTRONOMY & ASTROPHYSICS | NON-WKB MODELS | ACTIVE-REGION | MAGNETIC ELEMENTS | SLOW SOLAR-WIND | First ionization potential | Coronal heating | Alfven waves | Fractionation | Photospheric waves | Magnetohydrodynamics | Chromosphere | Coronal loops | Shear | Waves | Coupling (molecular) | Photosphere | Ionization | Heating | Ponderomotive forces | Corona | Coronal waves | Plasmas | Physics - Solar and Stellar Astrophysics | VELOCITY | FRACTIONATION | HEATING | IONS | SUN | SOLAR CORONA | ABUNDANCE | IONIZATION POTENTIAL | ALFVEN WAVES | PLASMA | PONDEROMOTIVE FORCE | ASTROPHYSICS, COSMOLOGY AND ASTRONOMY | RESONANCE | CHROMOSPHERE | TURBULENCE | POLARIZATION | FAR INFRARED RADIATION

waves | Sun: abundances | turbulence | Sun: chromosphere | RATE COEFFICIENTS | HELIUM ABUNDANCE | TRANSITION REGION | TORSIONAL MOTIONS | II SPICULES | ULTRAVIOLET SPECTRUM | ASTRONOMY & ASTROPHYSICS | NON-WKB MODELS | ACTIVE-REGION | MAGNETIC ELEMENTS | SLOW SOLAR-WIND | First ionization potential | Coronal heating | Alfven waves | Fractionation | Photospheric waves | Magnetohydrodynamics | Chromosphere | Coronal loops | Shear | Waves | Coupling (molecular) | Photosphere | Ionization | Heating | Ponderomotive forces | Corona | Coronal waves | Plasmas | Physics - Solar and Stellar Astrophysics | VELOCITY | FRACTIONATION | HEATING | IONS | SUN | SOLAR CORONA | ABUNDANCE | IONIZATION POTENTIAL | ALFVEN WAVES | PLASMA | PONDEROMOTIVE FORCE | ASTROPHYSICS, COSMOLOGY AND ASTRONOMY | RESONANCE | CHROMOSPHERE | TURBULENCE | POLARIZATION | FAR INFRARED RADIATION

Journal Article

NEW JOURNAL OF PHYSICS, ISSN 1367-2630, 07/2019, Volume 21, Issue 7, p. 73046

... related to the ponderomotive force due to the oscillating optical field. A recent study (Sun et al 2018 Proc. Natl Acad. Sci. USA 115 3285-9) derived this force...

POLARITONS | graphene nonlinearities | nonlocal response | ponderomotive force | PHYSICS, MULTIDISCIPLINARY | NONLINEARITY | Landau damping | Temperature effects | Graphene | Ponderomotive forces | Variations | Nonlinearity | Resonance | Polaritons | Two dimensional analysis | Regularization | Carrier density | Room temperature | Physics - Mesoscale and Nanoscale Physics

POLARITONS | graphene nonlinearities | nonlocal response | ponderomotive force | PHYSICS, MULTIDISCIPLINARY | NONLINEARITY | Landau damping | Temperature effects | Graphene | Ponderomotive forces | Variations | Nonlinearity | Resonance | Polaritons | Two dimensional analysis | Regularization | Carrier density | Room temperature | Physics - Mesoscale and Nanoscale Physics

Journal Article

Physics of Plasmas, ISSN 1070-664X, 2014, Volume 21, Issue 6, p. 62506

The local nonlinear forces induced by radio frequency (rf) waves are derived in inhomogeneous magnetized plasmas, where the inhomogeneity exists in the rf...

MOMENTUM TRANSPORT | TOROIDAL ROTATION | RUNAWAY ELECTRONS | GYROKINETIC THEORY | RADIOFREQUENCY WAVES | CURRENT DRIVE | PHYSICS, FLUIDS & PLASMAS | LOWER-HYBRID WAVES | TOKAMAK PLASMAS | ION-BERNSTEIN WAVES | SHEAR SUPPRESSION | Absorption | Particle interactions | Temperature effects | Wave-particle interactions | Flux | Momentum | Mathematical models | Inhomogeneity | Plasmas | Lorentz force | Cyclotrons | Diamagnetism | MAGNETIC FIELDS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | PONDEROMOTIVE FORCE | NONLINEAR PROBLEMS | LORENTZ FORCE | CYCLOTRON FREQUENCY | MODE CONVERSION | ABSORPTION | RADIOWAVE RADIATION

MOMENTUM TRANSPORT | TOROIDAL ROTATION | RUNAWAY ELECTRONS | GYROKINETIC THEORY | RADIOFREQUENCY WAVES | CURRENT DRIVE | PHYSICS, FLUIDS & PLASMAS | LOWER-HYBRID WAVES | TOKAMAK PLASMAS | ION-BERNSTEIN WAVES | SHEAR SUPPRESSION | Absorption | Particle interactions | Temperature effects | Wave-particle interactions | Flux | Momentum | Mathematical models | Inhomogeneity | Plasmas | Lorentz force | Cyclotrons | Diamagnetism | MAGNETIC FIELDS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | PONDEROMOTIVE FORCE | NONLINEAR PROBLEMS | LORENTZ FORCE | CYCLOTRON FREQUENCY | MODE CONVERSION | ABSORPTION | RADIOWAVE RADIATION

Journal Article

Physical Review Letters, ISSN 0031-9007, 09/2010, Volume 105, Issue 10, p. 105004

The concept of a ponderomotive force due to the intrinsic spin of electrons is developed...

WAVES | EXCITATION | PHYSICS | PHYSICS, MULTIDISCIPLINARY | ELECTROMAGNETIC PULSES | SPIN | ELECTRONS | MAGNETIZATION | ELECTRIC CURRENTS | FERMIONS | CURRENTS | PARTICLE PROPERTIES | ELEMENTARY PARTICLES | PULSES | ANGULAR MOMENTUM | LEPTONS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | PONDEROMOTIVE FORCE | SPIN ORIENTATION | NONLINEAR PROBLEMS | ORIENTATION | ELECTROMAGNETIC RADIATION | RADIATIONS

WAVES | EXCITATION | PHYSICS | PHYSICS, MULTIDISCIPLINARY | ELECTROMAGNETIC PULSES | SPIN | ELECTRONS | MAGNETIZATION | ELECTRIC CURRENTS | FERMIONS | CURRENTS | PARTICLE PROPERTIES | ELEMENTARY PARTICLES | PULSES | ANGULAR MOMENTUM | LEPTONS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | PONDEROMOTIVE FORCE | SPIN ORIENTATION | NONLINEAR PROBLEMS | ORIENTATION | ELECTROMAGNETIC RADIATION | RADIATIONS

Journal Article

Journal of Mathematical Physics, ISSN 0022-2488, 09/2016, Volume 57, Issue 9, p. 92902

In the general setting of the problem, the explicit compact formulae are derived for the ponderomotive forces in the macroscopic electrodynamics of moving media in the Minkowski and Abraham approaches...

ELECTROMAGNETIC ENERGY | PHYSICS, MATHEMATICAL | MOMENTUM | Conduction | Electrodynamics | Divergence | Constitutive relationships | Electromagnetism | Energy | Ponderomotive forces | Dependence | Momentum | Lorentz force | Electromagnetic fields

ELECTROMAGNETIC ENERGY | PHYSICS, MATHEMATICAL | MOMENTUM | Conduction | Electrodynamics | Divergence | Constitutive relationships | Electromagnetism | Energy | Ponderomotive forces | Dependence | Momentum | Lorentz force | Electromagnetic fields

Journal Article

Modern Physics Letters B, ISSN 0217-9849, 08/2013, Volume 27, Issue 21, p. 1350150

.... A consistent expression for the internal energy of the system is derived. The internal energy density and the continuity equation for the momentum lead to the derivation of ponderomotive forces...

Magnetoelectricity | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | PHYSICS, MATHEMATICAL

Magnetoelectricity | PHYSICS, CONDENSED MATTER | PHYSICS, APPLIED | PHYSICS, MATHEMATICAL

Journal Article

7.
Full Text
Microwave and plasma interaction in a rectangular waveguide: Effect of ponderomotive force

Journal of Applied Physics, ISSN 0021-8979, 07/2010, Volume 108, Issue 1, pp. 013109 - 013109-8

Studies on the propagation of high power microwave and its interaction with a plasma in a metallic waveguide are carried out. For this we consider the...

EXTERNAL MAGNETIC-FIELD | PHYSICS, APPLIED | PROPAGATION | DISCHARGES | Analysis | Electromagnetism | Wave propagation | PERMITTIVITY | PLASMA DENSITY | NUMERICAL SOLUTION | WAVELENGTHS | CALCULATION METHODS | PLASMA RADIAL PROFILES | EQUATIONS | ELECTRICAL PROPERTIES | MATHEMATICS | MATHEMATICAL SOLUTIONS | PLASMA | PONDEROMOTIVE FORCE | PHYSICAL PROPERTIES | RADIATIONS | DIELECTRIC PROPERTIES | AMPLITUDES | RUNGE-KUTTA METHOD | DIFFERENTIAL EQUATIONS | NUMERICAL ANALYSIS | MAXWELL EQUATIONS | WAVE PROPAGATION | WAVEGUIDES | ELECTRIC FIELDS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | MICROWAVE RADIATION | PARTIAL DIFFERENTIAL EQUATIONS | ELECTROMAGNETIC RADIATION | ITERATIVE METHODS

EXTERNAL MAGNETIC-FIELD | PHYSICS, APPLIED | PROPAGATION | DISCHARGES | Analysis | Electromagnetism | Wave propagation | PERMITTIVITY | PLASMA DENSITY | NUMERICAL SOLUTION | WAVELENGTHS | CALCULATION METHODS | PLASMA RADIAL PROFILES | EQUATIONS | ELECTRICAL PROPERTIES | MATHEMATICS | MATHEMATICAL SOLUTIONS | PLASMA | PONDEROMOTIVE FORCE | PHYSICAL PROPERTIES | RADIATIONS | DIELECTRIC PROPERTIES | AMPLITUDES | RUNGE-KUTTA METHOD | DIFFERENTIAL EQUATIONS | NUMERICAL ANALYSIS | MAXWELL EQUATIONS | WAVE PROPAGATION | WAVEGUIDES | ELECTRIC FIELDS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | MICROWAVE RADIATION | PARTIAL DIFFERENTIAL EQUATIONS | ELECTROMAGNETIC RADIATION | ITERATIVE METHODS

Journal Article

International Journal of Geometric Methods in Modern Physics, ISSN 0219-8878, 01/2017, Volume 14, Issue 1

...), we obtain the Lorentz force and Faraday's law of induction in the presence of a minimal length...

generalized uncertainty principle | minimal length | Lorentz force | ponderomotive force | Phenomenology of quantum gravity | SPACE | FIELD | COVARIANT DEFORMED ALGEBRA | PHYSICS | PHYSICS, MATHEMATICAL | Physics - General Physics

generalized uncertainty principle | minimal length | Lorentz force | ponderomotive force | Phenomenology of quantum gravity | SPACE | FIELD | COVARIANT DEFORMED ALGEBRA | PHYSICS | PHYSICS, MATHEMATICAL | Physics - General Physics

Journal Article

Physical Review E - Statistical, Nonlinear, and Soft Matter Physics, ISSN 1539-3755, 03/2011, Volume 83, Issue 3, p. 036410

In this paper we calculate the contribution to the ponderomotive force in a plasma from the electron spin using a recently developed model...

POLARIZED PLASMAS | PHYSICS | PHYSICS, MATHEMATICAL | PHYSICS, FLUIDS & PLASMAS | EQUATION | Physics - Plasma Physics | FLUIDS | VELOCITY | SPIN | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | ELECTRONS | FERMIONS | CORRELATIONS | PARTICLE PROPERTIES | ELEMENTARY PARTICLES | ANGULAR MOMENTUM | LEPTONS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | PONDEROMOTIVE FORCE

POLARIZED PLASMAS | PHYSICS | PHYSICS, MATHEMATICAL | PHYSICS, FLUIDS & PLASMAS | EQUATION | Physics - Plasma Physics | FLUIDS | VELOCITY | SPIN | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | ELECTRONS | FERMIONS | CORRELATIONS | PARTICLE PROPERTIES | ELEMENTARY PARTICLES | ANGULAR MOMENTUM | LEPTONS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | PONDEROMOTIVE FORCE

Journal Article

Physics of Plasmas, ISSN 1070-664X, 08/2013, Volume 20, Issue 8, p. 83107

A theory of relativistic ponderomotive force of transversely localized laser fields is presented by taking into account the nonlocal effects that correspond to higher order terms of the expansion parameter ϵ ≡ l / L , i.e...

LASER-PULSES | ELECTRONS | PHYSICS, FLUIDS & PLASMAS | RADIATION | Amplitudes | Lasers | Mathematical analysis | Ponderomotive forces | Transformations | Derivatives | Gages | Curvature | LASER RADIATION | PHASE SPACE | EXCURSIONS | PONDEROMOTIVE FORCE | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | CLASSICAL MECHANICS | LENGTH | RELATIVISTIC PLASMA | HAMILTONIANS | INTERACTIONS | RELATIVISTIC RANGE

LASER-PULSES | ELECTRONS | PHYSICS, FLUIDS & PLASMAS | RADIATION | Amplitudes | Lasers | Mathematical analysis | Ponderomotive forces | Transformations | Derivatives | Gages | Curvature | LASER RADIATION | PHASE SPACE | EXCURSIONS | PONDEROMOTIVE FORCE | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | CLASSICAL MECHANICS | LENGTH | RELATIVISTIC PLASMA | HAMILTONIANS | INTERACTIONS | RELATIVISTIC RANGE

Journal Article

Plasma Physics and Controlled Fusion, ISSN 0741-3335, 08/2015, Volume 57, Issue 8, pp. 85001 - 10

The effect of the non-relativistic ponderomotive force in the interaction of an intense laser pulse with isothermal and non-isothermal underdense collisional plasmas is studied...

ponderomotive force | nonlinear absorption | ohmic heating | ACCELERATION | VACUUM | FUSION | PHYSICS, FLUIDS & PLASMAS | DRIVEN | IGNITION | Ohmic | Controlled fusion | Heating | Lasers | Mathematical analysis | Ponderomotive forces | Absorption coefficient | Plasma (physics)

ponderomotive force | nonlinear absorption | ohmic heating | ACCELERATION | VACUUM | FUSION | PHYSICS, FLUIDS & PLASMAS | DRIVEN | IGNITION | Ohmic | Controlled fusion | Heating | Lasers | Mathematical analysis | Ponderomotive forces | Absorption coefficient | Plasma (physics)

Journal Article

Physical review. A, Atomic, molecular, and optical physics, ISSN 1050-2947, 06/2011, Volume 83, Issue 6

The ponderomotive force is derived for a relativistic charged particle entering an electromagnetic standing wave with a general three-dimensional field distribution and a nonrelativistic intensity...

Atomic and Molecular Physics, and Optics | ACCELERATION | INJECTION | LASER | BEAMS | PHYSICS, ATOMIC, MOLECULAR & CHEMICAL | ELECTRON PULSES | INTENSE | OPTICS | SCATTERING | Physics - Classical Physics | MAGNETIC FIELDS | DIFFERENTIAL EQUATIONS | ELECTROMAGNETIC FIELDS | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | ELECTRONS | EQUATIONS OF MOTION | ENERGY RANGE | ATOMIC AND MOLECULAR PHYSICS | EQUATIONS | FERMIONS | STANDING WAVES | EVALUATION | COMPARATIVE EVALUATIONS | THREE-DIMENSIONAL CALCULATIONS | PARTICLE ACCELERATORS | ELEMENTARY PARTICLES | RELATIVISTIC RANGE | LEPTONS | PONDEROMOTIVE FORCE | PARTIAL DIFFERENTIAL EQUATIONS | CHARGED PARTICLES | PERTURBATION THEORY | POLARIZATION

Atomic and Molecular Physics, and Optics | ACCELERATION | INJECTION | LASER | BEAMS | PHYSICS, ATOMIC, MOLECULAR & CHEMICAL | ELECTRON PULSES | INTENSE | OPTICS | SCATTERING | Physics - Classical Physics | MAGNETIC FIELDS | DIFFERENTIAL EQUATIONS | ELECTROMAGNETIC FIELDS | CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS | ELECTRONS | EQUATIONS OF MOTION | ENERGY RANGE | ATOMIC AND MOLECULAR PHYSICS | EQUATIONS | FERMIONS | STANDING WAVES | EVALUATION | COMPARATIVE EVALUATIONS | THREE-DIMENSIONAL CALCULATIONS | PARTICLE ACCELERATORS | ELEMENTARY PARTICLES | RELATIVISTIC RANGE | LEPTONS | PONDEROMOTIVE FORCE | PARTIAL DIFFERENTIAL EQUATIONS | CHARGED PARTICLES | PERTURBATION THEORY | POLARIZATION

Journal Article

Physics of Plasmas, ISSN 1070-664X, 02/2013, Volume 20, Issue 2, p. 22903

.... The derivations of the ponderomotive forces are done by assuming that the drift velocity in the ambient magnetic field is comparable to the particle velocity...

ACCELERATION | WAVE | MAGNETIC-FIELD | PLASMA | PHYSICS, FLUIDS & PLASMAS | Mathematical analysis | Electromagnetic waves | Ponderomotive forces | Derivation | Drift | Plasmas | Magnetic fields | Electric fields | MAGNETIC FIELDS | ELECTRIC FIELDS | ENERGY TRANSFER | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PONDEROMOTIVE FORCE | ELECTROMAGNETIC RADIATION | AMPLITUDES

ACCELERATION | WAVE | MAGNETIC-FIELD | PLASMA | PHYSICS, FLUIDS & PLASMAS | Mathematical analysis | Electromagnetic waves | Ponderomotive forces | Derivation | Drift | Plasmas | Magnetic fields | Electric fields | MAGNETIC FIELDS | ELECTRIC FIELDS | ENERGY TRANSFER | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PONDEROMOTIVE FORCE | ELECTROMAGNETIC RADIATION | AMPLITUDES

Journal Article

Optik, ISSN 0030-4026, 12/2018, Volume 175, pp. 250 - 255

We have investigated the ponderomotive force induced nonlinear interaction between terahertz (THz) wave and plasmas...

Ponderomotive force | Nonlinear interaction of THz waves and plasmas | THz driven optical modulator | GAUSSIAN LASER-BEAM | GENERATION | QUANTUM PLASMA | OPTICS | PULSES

Ponderomotive force | Nonlinear interaction of THz waves and plasmas | THz driven optical modulator | GAUSSIAN LASER-BEAM | GENERATION | QUANTUM PLASMA | OPTICS | PULSES

Journal Article

Physics of Plasmas, ISSN 1070-664X, 03/2007, Volume 14, Issue 5, pp. 055901 - 055901-6

.... In strongly inhomogeneous fields the ponderomotive force is phase dependent, and the particle dynamics resembles that of a quantum object in a conservative barrier...

GYRORESONANCE | PLASMA HEAT-FLOW | ELECTRON-BEAMS | PETAWATT LASER-PULSES | PHYSICS, FLUIDS & PLASMAS | CHARGED-PARTICLES | MAGNETIC-MIRROR | FIELD | STABILIZATION | CONFINEMENT | BROWNIAN MOTORS | INTEGRALS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | PONDEROMOTIVE FORCE | NONLINEAR PROBLEMS | BEAM-PLASMA SYSTEMS | PROBABILISTIC ESTIMATION | LARMOR PRECESSION | INHOMOGENEOUS FIELDS | POTENTIALS | PLASMA WAVES | PARTICLE BEAMS

GYRORESONANCE | PLASMA HEAT-FLOW | ELECTRON-BEAMS | PETAWATT LASER-PULSES | PHYSICS, FLUIDS & PLASMAS | CHARGED-PARTICLES | MAGNETIC-MIRROR | FIELD | STABILIZATION | CONFINEMENT | BROWNIAN MOTORS | INTEGRALS | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | PLASMA | PONDEROMOTIVE FORCE | NONLINEAR PROBLEMS | BEAM-PLASMA SYSTEMS | PROBABILISTIC ESTIMATION | LARMOR PRECESSION | INHOMOGENEOUS FIELDS | POTENTIALS | PLASMA WAVES | PARTICLE BEAMS

Journal Article

Plasma Science and Technology, ISSN 1009-0630, 10/2017, Volume 19, Issue 10, p. 105504

Here a new scheme for mode filtering is proposed. Based on the ponderomotive force effect, propagation of the microwave dual-mode through a plasma-filled metallic rectangular waveguide is investigated...

collisional plasma | mode convertor | ponderomotive force | mode filtering | FIELDS | DESIGN | PHYSICS, FLUIDS & PLASMAS | MICROWAVE

collisional plasma | mode convertor | ponderomotive force | mode filtering | FIELDS | DESIGN | PHYSICS, FLUIDS & PLASMAS | MICROWAVE

Journal Article

Proceedings of SPIE - The International Society for Optical Engineering, ISSN 0277-786X, 2011, Volume 8079

The ponderomotive force is derived for a relativistic charged particle entering an electromagnetic standing wave with a general three-dimensional field distribution and a nonrelativistic intensity...

Ponderomotive force | Polarization | Kapitza-Dirac effect | Ponderomotive scattering | Standing wave | Standing waves | Perturbation methods | Lasers | Mathematical analysis | Ponderomotive forces | Oscillations | Lorentz factor | Magnetic fields

Ponderomotive force | Polarization | Kapitza-Dirac effect | Ponderomotive scattering | Standing wave | Standing waves | Perturbation methods | Lasers | Mathematical analysis | Ponderomotive forces | Oscillations | Lorentz factor | Magnetic fields

Conference Proceeding

Optik, ISSN 0030-4026, 04/2018, Volume 158, pp. 1450 - 1459

.... The effect of the inertial ponderomotive force, ρm(u→⋅∇→) u→, on intensity of the second harmonic pulse and self focusing of laser pulse are considered...

Plasma | Self-focusing | Inertial ponderomotive force | The second harmonic generation | FIELD | COLLISIONLESS PLASMA | GAUSSIAN LASER-BEAM | UNDERDENSE PLASMAS | OPTICS

Plasma | Self-focusing | Inertial ponderomotive force | The second harmonic generation | FIELD | COLLISIONLESS PLASMA | GAUSSIAN LASER-BEAM | UNDERDENSE PLASMAS | OPTICS

Journal Article

Physics of Plasmas, ISSN 1070-664X, 02/2014, Volume 21, Issue 2, p. 23506

The interaction effect of a high-power microwave with the plasma in an elliptical waveguide taking into account the ponderomotive force is presented...

FIELDS | SHEET ELECTRON-BEAMS | PHYSICS, FLUIDS & PLASMAS | STABILITY | PROPAGATION | Plasma | Nonlinear equations | Conductors | Maxwell's equations | Plasma interactions | Density distribution | Plasma density | Propagation modes | Mathematical analysis | Electron pressure | Differential equations | Runge-Kutta method | Electron density | Electron energy | PERMITTIVITY | PLASMA DENSITY | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | MICROWAVE RADIATION | PONDEROMOTIVE FORCE | ELECTRON TEMPERATURE | MAXWELL EQUATIONS | ELECTRON DENSITY | HOMOGENEOUS PLASMA | RUNGE-KUTTA METHOD

FIELDS | SHEET ELECTRON-BEAMS | PHYSICS, FLUIDS & PLASMAS | STABILITY | PROPAGATION | Plasma | Nonlinear equations | Conductors | Maxwell's equations | Plasma interactions | Density distribution | Plasma density | Propagation modes | Mathematical analysis | Electron pressure | Differential equations | Runge-Kutta method | Electron density | Electron energy | PERMITTIVITY | PLASMA DENSITY | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | MICROWAVE RADIATION | PONDEROMOTIVE FORCE | ELECTRON TEMPERATURE | MAXWELL EQUATIONS | ELECTRON DENSITY | HOMOGENEOUS PLASMA | RUNGE-KUTTA METHOD

Journal Article

Physics of Plasmas, ISSN 1070-664X, 10/2015, Volume 22, Issue 10, p. 103112

The propagation characteristics of a Gaussian laser beam in collisional magnetized plasma are investigated by considering the ponderomotive and ohmic heating...

GENERATION | PHYSICS, FLUIDS & PLASMAS | RADIATION | PULSE | DIFFERENTIAL EQUATIONS | LASER RADIATION | MAGNETIC FIELDS | PERMITTIVITY | PLASMA DENSITY | CYCLOTRON FREQUENCY | LANGMUIR FREQUENCY | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | BEAM PROFILES | PONDEROMOTIVE FORCE | NONLINEAR PROBLEMS | PHOTON BEAMS | COLLISIONAL PLASMA | JOULE HEATING | DIELECTRIC MATERIALS

GENERATION | PHYSICS, FLUIDS & PLASMAS | RADIATION | PULSE | DIFFERENTIAL EQUATIONS | LASER RADIATION | MAGNETIC FIELDS | PERMITTIVITY | PLASMA DENSITY | CYCLOTRON FREQUENCY | LANGMUIR FREQUENCY | 70 PLASMA PHYSICS AND FUSION TECHNOLOGY | BEAM PROFILES | PONDEROMOTIVE FORCE | NONLINEAR PROBLEMS | PHOTON BEAMS | COLLISIONAL PLASMA | JOULE HEATING | DIELECTRIC MATERIALS

Journal Article

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