Obliquely propagating electron-acoustic solitary waves in magnetized plasmas: the role of trapped superthermal electrons

The properties of obliquely propagating electron-acoustic solitary waves (OPEASWs) have been investigated in a magnetized superthermal plasma (containing inertial cold electron species, inertialess electrons following Vasyliunas-Schamel distribution function, and static ions) via the fluid dynamical...

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Bibliographic Details
Published in:The European physical journal. D, Atomic, molecular, and optical physics Atomic, molecular, and optical physics, 2019-10, Vol.73 (10), Article 220
Main Authors: Sultana, Sharmin, Mannan, Abdul, Schlickeiser, Reinhard
Format: Article
Language:English
Subjects:
Acoustic propagation
Acoustic properties
Amplitudes
Applications of Nonlinear Dynamics and Chaos Theory
Atomic
Distribution functions
Hot electrons
Magnetic properties
Molecular
Obliqueness
Optical and Plasma Physics
Parameter modification
Perturbation methods
Physical Chemistry
Physics
Physics and Astronomy
Plasma
Plasmas (physics)
Quantum Information Technology
Quantum Physics
Regular Article
Saturn rings
Solitary waves
Spectroscopy/Spectrometry
Spintronics
Wave propagation
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Summary:The properties of obliquely propagating electron-acoustic solitary waves (OPEASWs) have been investigated in a magnetized superthermal plasma (containing inertial cold electron species, inertialess electrons following Vasyliunas-Schamel distribution function, and static ions) via the fluid dynamical approach. The reductive perturbation technique is employed to derive the Schamel equation and the solitary wave solution of the Schamel equation is used to examine the basic features of small but finite amplitude OPEASWs in such a magnetized plasma in the presence of trapped k -superthermal hot electron population. The basic features (width, amplitude, speed, etc.) of OPEASWs are found to be significantly modified by the different plasma configuration parameters, such as plasma superthermality, obliqueness, the particle trapping effect, and external magnetic field effect. The nature of electrostatic disturbances, that may propagate in different realistic space and laboratory plasma systems (e.g., in Saturn ring), is briefly discussed. Graphical abstract
ISSN:1434-6060
1434-6079
DOI:10.1140/epjd/e2019-100339-y