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Structure and evolution of magnetohydrodynamic solitary waves with Hall and finite Larmor radius effects

Artikel i vetenskaplig tidskrift
Författare E. Bello-Benitez
G. Sanchez-Arriaga
T. Passot
D. Laveder
Evangelos Siminos
Publicerad i Physical Review E
Volym 99
Nummer/häfte 2
ISSN 2470-0045
Publiceringsår 2019
Publicerad vid Institutionen för fysik (GU)
Språk en
Länkar dx.doi.org/10.1103/PhysRevE.99.0232...
Ämnesord nonlinear hydromagnetic-waves, homoclinic orbits, oblique solitons, alfven waves, fluid model, solar-wind, propagation, instability, turbulence, parallel, Physics
Ämneskategorier Fysik


Nonlinear and low-frequency solitary waves are investigated in the framework of the one-dimensional Hall-magnetohydrodynamic model with finite Larmor effects and two different closure models for the pressures. For a double adiabatic pressure model, the organization of these localized structures in terms of the propagation angle with respect to the ambient magnetic field theta and the propagation velocity C is discussed. There are three types of regions in the theta-C plane that correspond to domains where either solitary waves cannot exist, are organized in branches, or have a continuous spectrum. A numerical method valid for the two latter cases, which rigorously proves the existence of the waves, is presented and used to locate many waves, including bright and dark structures. Some of them belong to parametric domains where solitary waves were not found in previous works. The stability of the structures has been investigated by performing a linear analysis of the background plasma state and by means of numerical simulations. They show that the cores of some waves can be robust, but, for the parameters considered in the analysis, the tails are unstable. The substitution of the double adiabatic model by evolution equations for the plasma pressures appears to suppress the instability in some cases and to allow the propagation of the solitary waves during long times.

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