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Ion-acoustic solitary waves in a magnetized plasma with arbitrary electron equation of state (1983)

Lotko, W. ; Witt, E.

In: Other Sources

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Publication Date: 2019-06-28

Description: The oblique propagation of fully nonlinear, slow ion-acoustic solitary waves in a collisionless, low-beta, magnetized plasma is examined. The analysis includes the effects of a finite ion pressure, electron trapping, and multicomponent particle populations. The existence of both compressive and rarefactive modes propagating obliquely to the magnetic field in a plasma with two distinct Boltzmann electron populations and cold ions is demonstrated. It is shown that paired electrostatic shocks observed over the earth's auroral zone may be closely related to the rarefactive modes. As a measure of the collisionless dissipation encountered by the solitary waves, the linear response of the plasma to slow ion-acoustic waves is also examined.

Keywords: PLASMA PHYSICS

Type: Physics of Fluids (ISSN 0031-9171); 26; Aug. 198

Format: text

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Oxygen acoustic solitary waves in a magnetized plasma (1989)

Qian, S. ; Lotko, W. ; Hudson, M. K.

In: Other Sources

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Publication Date: 2019-07-12

Description: Ion-acoustic solitary waves in a magnetized plasma containing an arbitrary mixture of H(+) and O(+) ions are studied. A nonlinear wave equation has been derived from the Poisson-Vlasov equations, including a uniform magnetic field and dissipation due to reflected electrons. When dissipation is ignored, the equation has soliton solutions associated with both oxygen and hydrogen acoustic modes, which can be either rarefactive or compressive depending on the ion concentrations and the electron/ion temperature ratio and, more weakly, on the bulk drifts of the species. If electron reflection is included, the solitary wave can be intensified. Under somewhat restrictive conditions the oxygen solitary wave is rarefactive and propagates with a velocity comparable to that observed by the Viking satellite. The three-dimensional solitons obey a relation of scales parallel to the magnetic field and in the transverse direction. Computer simulations of one-dimensional versions of the nonlinear wave equation are presented.

Keywords: PLASMA PHYSICS

Type: Journal of Geophysical Research (ISSN 0148-0227); 94; 1339-134

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Dynamics of localized ion-acoustic waves in a magnetized plasma (1988)

Qian, S. ; Hudson, M. K. ; Lotko, W.

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Publication Date: 2019-07-12

Description: The evolution of negative potential pulses in a magnetized plasma is studied. A three-dimensional nonlinear ion-acoustic wave equation, including nonstationary effects of reflected electrons, has been derived from the Poisson-Vlasov equations with uniform magnetic field. The studies show that a negative potential pulse can be enhanced by drifting electrons. The growing pulse develops asymmetrically with an oscillatory precursor and a local potential jump resembling the early phase of weak double layer formation.

Keywords: PLASMA PHYSICS

Type: Physics of Fluids (ISSN 0031-9171); 31; 2190-220

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