On the shock wave structures in anisotropy magnetoplasmas
Dissipative system
Inertia
QC1-999
Mechanics
01 natural sciences
Amplitude
Electron
Quantum mechanics
Plasma
0103 physical sciences
Computational physics
Shock (circulatory)
Classical mechanics
Internal medicine
Quantum electrodynamics
Physics
Nonlinear Solitary Waves
Dusty Plasmas: Interdisciplinary Research Field
Astronomy and Astrophysics
Statistical and Nonlinear Physics
Atomic and Molecular Physics, and Optics
Space Weather and Magnetospheric Physics
Physics and Astronomy
Shock wave
Dissipation
Physical Sciences
Nonlinear system
Anisotropy
Medicine
Rogue Waves in Nonlinear Systems
DOI:
10.1063/5.0173000
Publication Date:
2023-10-06T04:31:45Z
AUTHORS (6)
ABSTRACT
In this work, the propagation of nonlinear electrostatic shock wave structures in an anisotropy pressure magnetoplasma composed of warm inertial ions and inertia-less Maxwellian electrons is reported. For this purpose, the technique of reductive perturbation is applied for reducing fluid equations of the current model to the Korteweg–de Vries Burgers (KdVB) equation with a second-order dissipative term and the KdVB–Kuramoto (KBK) equation with both second- and fourth-order dissipative terms. The impact of various plasma parameters, including the parallel ion pressure, perpendicular ion pressure, and dissipation parameter, on the significant characteristics of the shock wave profile is examined and discussed. In addition, a comparison between the profiles of KdVB shocks and KdVB–Kuramoto shocks is reported. We expect that KBK shock wave amplitudes become larger than the KdVB ones by taking the fourth-order dissipative into consideration. Thus, the results of the KBK equation may treat the difference between the theoretical and laboratory results or satellite observations.
SUPPLEMENTAL MATERIAL
Coming soon ....
REFERENCES (61)
CITATIONS (8)
EXTERNAL LINKS
PlumX Metrics
RECOMMENDATIONS
FAIR ASSESSMENT
Coming soon ....
JUPYTER LAB
Coming soon ....