Document Zbl 1498.76115

Douanla, D. V.; Alim; Tiofack, C. G. L.; Mohamadou, A.; El-Sherif, L. S.

Three-dimensional dissipative ion-acoustic rogue waves in magnetized plasma with adiabatic ions and nonextensive electrons. (English) Zbl 1498.76115

Waves Random Complex Media 32, No. 4, 1847-1861 (2022).

MSC:

76X05	Ionized gas flow in electromagnetic fields; plasmic flow
76E25	Stability and instability of magnetohydrodynamic and electrohydrodynamic flows
76M45	Asymptotic methods, singular perturbations applied to problems in fluid mechanics
78A35	Motion of charged particles

Keywords:

reductive perturbation method; modified nonlinear Schrödinger equation; modulational instability; energy dissipation

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Full Text: DOI

References:

[1]	Leontovich, MA., Reviews of plasma physics (2012), Berlin: Springer Science and Business Media, Berlin
[2]	Ikezawa, S.; Nakamura, YJ., Observation of electron plasma waves in plasma of two-temperature electrons, Phys Soc Jpn, 50, 962-967 (1981)
[3]	Dubouloz, N.; Pottelette, R.; Malingre, M., Detailed analysis of broadband electrostatic noise in the dayside auroral zone, J Geophys Res, 96, 3565-3579 (1991)
[4]	Mozer, FS; Ergun, R.; Temarin, M., New features of time domain electric-field structures in the auroral acceleration region, Phys Rev Lett, 79, 1281-1284 (1997)
[5]	Ikezi, H., Experiments on ion-acoustic solitary waves, Phys Fluids, 16, 1668-1675 (1973)
[6]	Watanabe, S., Ion-acoustic solitons excited by a single grip, J Plasma Phys, 14, 353-364 (1975)
[7]	Selwyn, GS; Heidenreich, JE; Haller, KL., Particle trapping phenomena in radio frequency plasmas, Appl Phys Lett, 57, 1876-1878 (1990)
[8]	Boufendi, L.; Bouchoule, A.; Porteous, RK, Particle-particle interactions in dusty plasmas, J Appl Phys, 73, 2160-2162 (1993)
[9]	Gondhalekar, A.; Stangeby, PC; Elder, JD., Investigations of impurity control in JET using fuelling, and interpretation of experiments using the LIM impurity code, Nucl Fusion, 34, 247-260 (1994)
[10]	Kolbasov, BN; Kukushkin, AB; RantsevKartinov, VA, Similarity of micro- and macrotubules in tokamak dust and plasma, Phys Lett A, 269, 363-367 (2000)
[11]	Bacha, M.; Soufiane, B.; Tribeche, M., Ion-acoustic rogue waves in a plasma with a q-nonextensive electron velocity distribution, Astrophys Space Sci, 341, 591-595 (2012)
[12]	El-Labany, SK; Moslem, WM; El-Bedwehy, NA, Rogue wave in Titan’s atmosphere, Astrophys Space Sci, 338, 3-8 (2012) · Zbl 1238.85021
[13]	Jannat, N.; Ferdousi, M.; Mamun, AA., Ion-acoustic Gardner solitons in a four-component nonextensive multi-ion plasma, Plasma Phys Rep, 42, 678-686 (2016)
[14]	Mahmood, S.; Mushtaq, A.; Saleem, H., Ion acoustic solitary wave in homogeneous magnetized electron-positron-ion plasmas, New J Phys, 5, 28 (2003)
[15]	Bacha, M.; Gougam, LA; Tribeche, M., Ion-acoustic rogue waves in magnetized solar wind plasma with nonextensive electrons, Physica A, 466, 199-210 (2017) · Zbl 1400.82264
[16]	Kharif, C.; Efim, P.; Alexey, S., Rogue waves in the ocean (2008), Berlin: Springer Science and Business Media, Berlin
[17]	Aljahdaly, NH; El-Tantawy, SA., Simulation study on nonlinear structures in nonlinear dispersive media, Chaos, 30 (2020) · Zbl 1437.76055
[18]	Irfan, M.; Ali, S.; El-Tantawy, SA, Three dimensional ion-acoustic rogons in quantized anisotropic magnetoplasmas with trapped/untrapped electrons, Chaos, 29 (2019)
[19]	Almutlak, SA; El-Tantawy, SA; Shan, SA, Multidimensional freak waves in electron depleted dusty magnetoplasmas having superthermal ion with two temperatures, Eur Phys J Plus, 134, 513 (2019)
[20]	Almutalk, SA; El-Tantawy, SA; El-Awady, EI, On the numerical solution of nonplanar dust-acoustic super rogue waves in a strongly coupled dusty plasma, Phys Lett A, 383, 1937-1941 (2019) · Zbl 1482.76150
[21]	El-Tantawy, SA; Aboelenen, T.; Ismaeel, SME., Local discontinuous Galerkin method for modeling the nonplanar structures (solitons and shocks) in an electronegative plasma, Phys Plasmas, 26 (2019)
[22]	Bespalov, VI; Talanov, VI., Filamentary structure of light beams in nonlinear liquids, Pis’ma v Zurnal Experim Teoret Fiziki, 3, 471 (1966)
[23]	Ganshin, AN; Efimov, VB; Kolmakov, GV, Observation of an inverse energy cascade in developed acoustic turbulence in superfluid helium, Phys Rev Lett, 101 (2008)
[24]	Onorato, M.; Residori, S.; Bortolozzo, U., Rogue waves and their generating mechanisms in different physical contexts, Phys Rep, 528, 47-89 (2013)
[25]	Shats, M.; Punzmann, H.; Xia, H., Capillary rogue waves, Phys Rev Lett, 104 (2010)
[26]	Asbridge, JR; Bame, SJ; Strong, IB., Outward flow of protons from the earth’s bow shock, J Geophys Res, 73, 5777-5782 (1968)
[27]	Kulikov, YN; Lammer, H.; Lichtenegger, HIM, A comparative study of the influence of the active young Sun on the early atmospheres of Earth, Venus, and Mars, Space Sci Rev, 129, 207-243 (2007)
[28]	Futaana, Y.; Machida, S.; Saito, Y., Moon-related nonthermal ions observed by Nozomi: species, sources, and generation mechanisms, J Geophys Res Space, 108, SMP-15 (2003)
[29]	Divine, N.; Garrett, HB., Charged particle distributions in Jupiter’s magnetosphere, J Geophys Res Space, 88, 6889-6903 (1983)
[30]	Krimigis, SM; Carbary, JF; Keath, EP, General characteristics of hot plasma and energetic particles in the Saturnian magnetosphere: results from the Voyager spacecraft, J Geophys Res Space, 88, 8871-8892 (1983)
[31]	Renyi, A., On a new axiomatic theory of probability, Acta Math Acad Sci Hung, 6, 285-335 (1955) · Zbl 0067.10401
[32]	Tsallis, C., Possible generalization of Boltzmann-Gibbs statistics, J Stat Phys, 52, 479-487 (1988) · Zbl 1082.82501
[33]	Rax, JM., Physique des plasmas: cours et applications (2009), Paris: Dunod, Paris
[34]	El-Tantawy, SA., Ion-acoustic waves in ultracold neutral plasmas: modulational instability and dissipative rogue waves, Phys Lett A, 381, 787-791 (2017)
[35]	Alinejad, H.; Shahmansouri, M., Evolution of dissipative low-frequency rogue waves in superthermal dusty plasmas, IEEE Trans Plasma Sci, 47, 4378-4384 (2019)
[36]	Shahein, RA; El-Shehri, JH., Bifurcation analysis of dissipative rogue wave in electron-positron-ion plasma with relativistic ions and superthermal electrons, Chaos Soliton Fract, 128, 114-122 (2019) · Zbl 1483.35019
[37]	Xue, JK., Modulation of dust acoustic waves with non-adiabatic dust charge fluctuations, Phys Lett A, 320, 226-233 (2003) · Zbl 1065.76549
[38]	Amin, MR., Modulation of a quantum positron acoustic wave, Astrophys Space Sci, 359, 2 (2015)
[39]	Guo, S.; Mei, L., Three-dimensional dust-ion-acoustic rogue waves in a magnetized dusty pair-ion plasma with nonthermal nonextensive electrons and opposite polarity dust grains, Phys Plasmas, 21 (2014)
[40]	Bains, AS; Tribeche, M.; Gill, TS., Modulational instability of electron-acoustic waves in a plasma with a q-nonextensive electron velocity distribution, Phys Lett A, 375, 2059-2063 (2011)
[41]	Xue, JK., Modulational instability of multi-dimensional dust ion-acoustic waves, Phys Lett A, 330, 390-395 (2004)
[42]	Akhmediev, N.; Ankiewicz, A.; Taki, M., Waves that appear from nowhere and disappear without a trace, Phys Lett A, 373, 675-678 (2009) · Zbl 1227.76010
[43]	Yan, Z., Nonautonomous ‘rogons’ in the inhomogeneous nonlinear Schrödinger equation with variable coefficients, Phys Lett A, 374, 672-679 (2010) · Zbl 1235.35266
[44]	El-Tantawy, S.; Salas, A.; Hammadd, M., Impact of dust kinematic viscosity on the breathers and rogue waves in a complex plasma having kappa distributed particles, Waves Random Complex Medium (2019) · Zbl 1495.76135 · doi:10.1080/17455030.2019.1698790

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