Head-on collision of ion-acoustic (modified) Korteweg–de Vries solitons in Saturn's magnetosphere plasmas with two temperature superthermal electrons

Hashmi, T.; Jahangir, R.; Masood, W.; Alotaibi, B. M.; Ismaeel, Sherif M. E.; El-Tantawy, S. A.

doi:10.1063/5.0171220

Cited by 18 publications

(1 citation statement)

References 53 publications

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“…In future work, we can apply the proposed method to study and analyze many evolution equations that are used to describe the characteristics of many nonlinear phenomena that arise in different plasma systems. For example, it is possible to study the effect of the time and space fractional parameters on the properties of solitary and shock waves that arise within the various plasma systems, which are described by the Korteweg-de Vries (KdV)-type equations with third-order dispersion (e.g., KdV, modified KdV (mKdV), Extended/Gardner KdV equation, KdV-Burgers equation, and so on) [41][42][43][44][45][46][47][48][49][50][51][52] and higher-order dispersion (e.g., Kawahara-type equation with some physical effects) and many other related equations [53][54][55][56][57][58][59][60][61][62][63][64], whether in their integral or nonintegral form. Also, this method can be applied to investigating modulated nonlinear structures such as modulated envelope solitons, modulated cnoidal waves, rogue waves and breathers that are described by the standard form of undamped planar nonlinear Schrödinger equation (NLSE) [65][66][67][68][69][70][71][72][73][74] and the damped or nonplanar NLSE [75][76][77][78][79]…”

Section: Discussionmentioning

confidence: 99%

A novel analytical technique for analyzing the (3+1)-dimensional fractional calogero- bogoyavlenskii-schiff equation: investigating solitary/shock waves and many others physical phenomena

Noor,

Alyousef,

Shafee

et al. 2024

Phys. Scr.

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This work presents a thorough analysis of soliton wave phenomena in the (3+1)-dimensional Fractional Calogero-Bogoyavlenskii-Schiff equation (FCBSE) with Caputo’s derivatives through the use of a novel analytical technique known as the modified Extended Direct Algebraic Method (mEDAM). By converting nonlinear Fractional Partial Differential equations (FPDE) into integer-order Nonlinear Ordinary Differential equations (NODE), and then using closed-form series solutions to translate the NODE into an algebraic system of equations, this method allows us to derive families of soliton solutions, which include kink waves, lump waves, breather waves, and periodic waves, exposing new insights into the behavior and distinctive features of soliton waves in the FCBSE. By including contour and 3D graphics, the behaviors of a few selected soliton solutions are well depicted, showcasing their amplitude, shape, and propagation characteristics. The results enhance our understanding of the FCBSE and show that the mEDAM is a valuable tool for studying soliton wave phenomena. This work creates new opportunities for studying wave phenomena in more intricately constructed nonlinear FPDEs (NFPDEs).

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Section: Discussionmentioning

confidence: 99%

A novel analytical technique for analyzing the (3+1)-dimensional fractional calogero- bogoyavlenskii-schiff equation: investigating solitary/shock waves and many others physical phenomena

Noor,

Alyousef,

Shafee

et al. 2024

Phys. Scr.

Self Cite

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On the integrability, multi-shocks, high-order kinky-breathers, L-lump–kink solutions for the non-autonomous perturbed potential Kadomtsev–Petviashvili equation

Alhejaili,

Roy,

Raut

et al. 2024

Nonlinear Dyn

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Kinetic Alfvén solitary waves in a low-β plasma with regularized kappa-distributed electrons

Albalawi,

Khalid,

Tiofack

et al. 2024

AIP Advances

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This study examines the characteristics of small-amplitude kinetic Alfvén waves (KAWs) in a typical magnetoplasma, where both ions and electrons are considered to have a regularized kappa distribution (RKD). The restrictions imposed on the standard Kappa distribution function will be removed by considering the RKD function. The RKD can also be used for kappa areas for spectral index κ < 3/2. We then use the Korteweg–de Vries equation to investigate the KAWs in this model, which we obtained from the reductive perturbation method. It is observed that the equation’s nonlinear and dispersive coefficients are functions of the Kummar functions and the cut-off parameter. It is found that the nonlinear and dispersive coefficients of this equation depend on the Kummar functions and the cut-off parameter. Due to the negativity of the coefficients of the wave equation, only compressive KAWs can exist and propagate in this model. The numerical results demonstrate a positive correlation between the soliton’s profile (amplitude and width) with an increase in the cut-off parameter. Conversely, the superthermality has a negative influence on the soliton profile. The influence of the soliton’s propagation angle on the magnetic field’s direction is investigated. It is found that the solitary wave will not propagate in the ambient when the propagation angle θ becomes 0 or 90. Overall, the results obtained from this research can be used in space and laboratory plasmas with low β that have non-Maxwellian electrons.

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Head-on collision of ion-acoustic (modified) Korteweg–de Vries solitons in Saturn's magnetosphere plasmas with two temperature superthermal electrons

Cited by 18 publications

References 53 publications

A novel analytical technique for analyzing the (3+1)-dimensional fractional calogero- bogoyavlenskii-schiff equation: investigating solitary/shock waves and many others physical phenomena

A novel analytical technique for analyzing the (3+1)-dimensional fractional calogero- bogoyavlenskii-schiff equation: investigating solitary/shock waves and many others physical phenomena

On the integrability, multi-shocks, high-order kinky-breathers, L-lump–kink solutions for the non-autonomous perturbed potential Kadomtsev–Petviashvili equation

Kinetic Alfvén solitary waves in a low-β plasma with regularized kappa-distributed electrons

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