On the characteristics of obliquely propagating electrostatic structures in non-Maxwellian plasmas in the presence of ion pressure anisotropy

Adnan, Muhammad; Qamar, Anisa; Mahmood, S.; Kourakis, Ioannis

doi:10.1063/1.4978613

Cited by 16 publications

(19 citation statements)

References 37 publications

(51 reference statements)

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“…By multiplying

\frac{d S}{d\xi}

both sides of Equation (11) and then after integration, we get energy conservation equation in the following form (for the detail derivation see appendix in ref. [40])

\frac{1}{2}{\left(\frac{d\Phi}{d\xi}\right)}^2+\Psi \left(\Phi, \kappa, M,\Omega \right)=0,

where

\Psi \left(\phi, \kappa, M,\Omega \right)={\Omega}^2\frac{\Psi_1\left(\Phi, \kappa, M\right)}{\Psi_2\left(\Phi, \kappa, M\right)},

is the “pseudopotential” function, and

{\Psi}_1\left(\Phi, \kappa, M\right)

and

{\Psi}_2\left(\Phi, \kappa, M\right)

given by

\begin{matrix} true \\ {normalΨ}_{1} & = \frac{1}{10} ({(1 goodbreak+ κ)}^{\frac{5}{3}} + (...) \end{matrix}

…”

Section: Arbitrary Amplitude Electrostatic Oblique Solitary Waves Exc...mentioning

confidence: 99%

“…By multiplying dS d𝜉 both sides of Equation ( 11) and then after integration, we get energy conservation equation in the following form (for the detail derivation see appendix in ref. [40]) 1 2…”

Section: Arbitrary Amplitude Electrostatic Oblique Solitary Waves Exc...mentioning

confidence: 99%

“…Later on Sagdeev approach extended for the description of magnetized plasmas. [36][37][38][39][40][41] In this manuscript, we investigated electrostatic ions acoustic solitary waves composed of inertia-less electrons with both spin-up ( n ↑ ) and spin-down…”

Section: Introductionmentioning

confidence: 99%

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The arbitrary amplitude of a solitary pulse propagating obliquely in electron spin‐polarized plasma

Gul

Ahmad

2022

Contributions to Plasma Physics

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A Separated Spin Evolution Quantum Hydrodynamics Model is employed to investigate arbitrary amplitude ion‐acoustic waves in magnetized plasma, which consists of inertia‐less degenerated electrons with spin‐up n↑$$ {n}_{\uparrow } $$ and spin‐down n↓$$ {n}_{\downarrow } $$ states, as well as inertial classical ions. In a two‐dimensional plasma geometry, a homogeneous magnetic field is assumed to be directed along the z‐axis, that is, boldB=B0truez^$$ \mathbf{B}={B}_0\hat{z} $$. In the linear analysis, two branches of waves propagation are found to occur in the oblique direction. The characteristics of large‐amplitude ions solitary waves propagation in oblique direction are studied through an energy‐balance equation, by applying a Sagdeev potential approach. The parametric role of the spin density polarization ratio κ$$ \kappa $$ on the properties of solitary wave structures, as well as other important plasma parameters, is traced analytically. The scope of our work is significant to study dilute magnetic semiconductors, magnetosphere, and as well as astrophysical systems.

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“…By multiplying

\frac{d S}{d\xi}

both sides of Equation (11) and then after integration, we get energy conservation equation in the following form (for the detail derivation see appendix in ref. [40])

\frac{1}{2}{\left(\frac{d\Phi}{d\xi}\right)}^2+\Psi \left(\Phi, \kappa, M,\Omega \right)=0,

where

\Psi \left(\phi, \kappa, M,\Omega \right)={\Omega}^2\frac{\Psi_1\left(\Phi, \kappa, M\right)}{\Psi_2\left(\Phi, \kappa, M\right)},

is the “pseudopotential” function, and

{\Psi}_1\left(\Phi, \kappa, M\right)

and

{\Psi}_2\left(\Phi, \kappa, M\right)

given by

\begin{matrix} true \\ {normalΨ}_{1} & = \frac{1}{10} ({(1 goodbreak+ κ)}^{\frac{5}{3}} + (...) \end{matrix}

…”

Section: Arbitrary Amplitude Electrostatic Oblique Solitary Waves Exc...mentioning

confidence: 99%

Section: Arbitrary Amplitude Electrostatic Oblique Solitary Waves Exc...mentioning

confidence: 99%

See 1 more Smart Citation

The arbitrary amplitude of a solitary pulse propagating obliquely in electron spin‐polarized plasma

Gul

Ahmad

2022

Contributions to Plasma Physics

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“…The electron kinematic fluid viscosity ( μ c ‖,⊥ ) is also normalized into dimensionless parameter (i.e.,

η_{c false‖, ⊥} = μ_{c false‖, ⊥} \frac{ω_{p h}}{C_{e}^{2}}

). The external magnetic field introduces an anisotropy in the electron pressure which splits the pressure tensor into two components in the directions perpendicular and parallel to the direction of magnetic field (Adnan et al, , ). They studied the effect of anisotropic pressure on nonlinear ion acoustic excitations in magnetized e‐p‐i plasmas by employing Sagdeev pseudo‐potential and reductive perturbation technique under the influence of superthermal distribution.…”

Section: Fluid Modelmentioning

confidence: 99%

Effect of Anisotropic Pressure on Electron Acoustic Oscillatory and Monotonic Shocks in Superthermal Magnetoplasma

Singh

Saini

2019

Radio Science

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Nonlinear oscillatory and monotonic electron acoustic shock waves in dissipative magnetorotating electron-positron-ion plasmas containing cold dynamical electrons, superthermal electrons, and positrons have been analyzed in the stationary background of massive positive ions. The Korteweg de-Vries-Burgers equation which describes the dynamics of the nonlinear shock structures is derived by using amplitude reductive perturbation technique. The quantitative analysis of impact of different physical parameters on the shock structures is presented here. The electron fluid viscosity plays a pivotal role for the transition of electron acoustic (EA) monotonic to oscillatory shocks and vice versa. It is remarkable that the shock structures are sensitive to the Coriolis force, obliqueness, electron temperature, and the positrons concentration. The present work may be employed to explore and to understand the formation of electron acoustic shock structures in the space and laboratory plasmas with superthermal electrons and positrons under magnetorotating effects, especially in auroral zone, Van Allen radiation belts, planetary magnetospheres, pulsars, black-hole magnetospheres, etc.

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“…In such situations, one needs to solve two energy equations associated with the thermal pressures p and p ⊥ (relative to the magnetic filed). The features of such anisotropic system can be uncovered by theory presented by Chew-Golberger-Low in 1956, famous as (CGL) or double adiabatic theory [31][32][33].…”

Section: Introductionmentioning

confidence: 99%

Effect of Pressure Anisotropy on Nonlinear Periodic Waves in a Magnetized Superthermal Electron-Positron-Ion Plasma

et al. 2019

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The propagation properties of electrostatic cnoidal waves (periodic waves) and solitons are studied in a magnetized electron-positron-ion (EPI) plasma bearing ion pressure anisotropy and superthermality. In a two-dimensional geometry, we considered the ions to be warm having pressure anisotropy due to magnetic field. The anisotropic ions are modeled via double adiabatic Chew-Golberger-Low (CGL) theory and the lighter species (electron and positron) are following kappa distributions. A Korteweg-de Vries (KdV)-type equation is derived by employing reductive perturbation technique, and obtained the nonlinear periodic waves solutions with appropriate boundary conditions. The anisotropy in the ion thermal pressure relative to the external magnetic field (different values in parallel and perpendicular directions) have significant effects on the characteristics of cnoidal waves. It is observed that by increasing the ion parallel and perpendicular pressure (keeping the relative anisotropy) tends to reduce the wavelength of the cnoidal wave structure, while the amplitude tends to increase. The influence of superthermality of electron and positron, the positron content and strength of the external magnetic field on the cnoidal waves are studied in detail. Furthermore, phase portrait analysis is carried out and traced out the equilibrium points around which nonlinear periodic waves can be formed. The saddle points which correspond to the homoclinic orbits are also shown. The investigation can be useful in exploring the nonlinear wave dynamics in both laboratory and space plasma where ion pressure anisotropy and superthermality exist.

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On the characteristics of obliquely propagating electrostatic structures in non-Maxwellian plasmas in the presence of ion pressure anisotropy

Cited by 16 publications

References 37 publications

The arbitrary amplitude of a solitary pulse propagating obliquely in electron spin‐polarized plasma

The arbitrary amplitude of a solitary pulse propagating obliquely in electron spin‐polarized plasma

Effect of Anisotropic Pressure on Electron Acoustic Oscillatory and Monotonic Shocks in Superthermal Magnetoplasma

Effect of Pressure Anisotropy on Nonlinear Periodic Waves in a Magnetized Superthermal Electron-Positron-Ion Plasma

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