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Journal articles on the topic 'Magnetoplasma'

Author: Grafiati
Published: 4 June 2021
Last updated: 7 September 2023

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1

SHUKLA, P. K. "Excitation of electrostatic ion-cyclotron-like modes by the electron density ripple in dusty magnetoplasmas." Journal of Plasma Physics 75, no. 4 (August 2009): 433–36. http://dx.doi.org/10.1017/s0022377809008071.

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AbstractIt is shown that electrostatic ion-cyclotron (EIC)-like modes can be excited by the pre-existing electron density ripple across the external magnetic field in a dusty magnetoplasma. For this purpose, we use the ion continuity and momentum equations, together with the Boltzmann-distributed electrons, and derive the standard Mathieu equation. The latter admits unstable solutions, demonstrating that the EIC-like modes in dusty magnetoplasmas can be driven due to the free energy in the electron density ripple.
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2

MARKLUND, M., L. STENFLO, and P. K. SHUKLA. "Magnetosonic solitons in a dusty plasma slab." Journal of Plasma Physics 74, no. 5 (October 2008): 601–5. http://dx.doi.org/10.1017/s0022377807006964.

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AbstractThe existence of magnetosonic solitons in dusty plasmas is investigated. The nonlinear magnetohydrodynamic equations for a warm dusty magnetoplasma are thus derived. A solution of the nonlinear equations is presented. It is shown that, owing to the presence of dust, static structures are allowed. This is in sharp contrast to the formation of the so-called shocklets in usual magnetoplasmas. A comparatively small number of dust particles can thus drastically alter the behavior of the nonlinear structures in magnetized plasmas.
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3

Rahman, Ata-ur, A. Qamar, S. Naseer, and S. N. Naeem. "Oblique ion acoustic excitations in an ultra-relativistic degenerate dense magnetoplasma." Canadian Journal of Physics 95, no. 7 (July 2017): 655–61. http://dx.doi.org/10.1139/cjp-2016-0592.

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The linear and nonlinear propagation of ion acoustic waves is considered in a degenerate magnetoplasma, composed of relativistic degenerate electrons and an inertial ion fluid. A linear dispersion relation is derived in the linear approximation. The Sagdeev pseudopotential approach is used to investigate the properties of arbitrary amplitude, obliquely propagating ion acoustic solitary waves. The expression for the lower and upper Mach numbers for the existence of magnetized ion acoustic solitons has also been derived. The significant influence on the properties of soliton structures of relevant physical parameters, such as the plasma number density, the obliqueness (the angle between soliton propagation direction and magnetic field), and the soliton speed is also investigated. At the end, analytical results are supplemented through numerical analysis by using typical representative parameters consistent with degenerate and ultra-relativistic magnetoplasmas of astrophysical regimes.
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4

Rasheed, A., M. Jamil, Young-Dae Jung, A. Sahar, and M. Asif. "The Exchange-Correlation Field Effect over the Magnetoacoustic-Gravitational Instability in Plasmas." Zeitschrift für Naturforschung A 72, no. 10 (September 26, 2017): 915–21. http://dx.doi.org/10.1515/zna-2017-0164.

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AbstractJeans instability with magnetosonic perturbations is discussed in quantum dusty magnetoplasmas. The quantum and smaller thermal effects are associated only with electrons. The quantum characteristics include exchange-correlation potential, recoil effect, and Fermi degenerate pressure. The multifluid model of plasmas is used for the analytical study of this problem. The significant contribution of electron exchange is noticed on the threshold value of wave vector and Jeans instability. The presence of electron exchange and correlation effects reduce the time to stabilise the phenomenon of self-gravitational collapse of massive species. The results of Jeans instability by magnetosonic perturbations at quantum scale help to disclose the details of the self-gravitating dusty magnetoplasma systems.
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5

SHUKLA, P. K., and L. STENFLO. "Quantum Hall-MHD equations for a non-uniform dense magnetoplasma with electron temperature anisotropy." Journal of Plasma Physics 74, no. 5 (October 2008): 575–79. http://dx.doi.org/10.1017/s0022377808007290.

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AbstractNonlinear quantum Hall-MHD equations for a warm dense magnetoplasma with an anisotropic electron pressure are derived. The nonlinear equations include the quantum force associated with electron tunneling effects. The newly found equations can be used to investigate the dense plasma stability, as well as different types of waves, instabilities, and nonlinear structures in a warm dense magnetoplasma.
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6

Lüttgen, Andrea A. E., and Keith G. Balmain. "Nonreciprocal magnetoplasma sheath waves." Radio Science 31, no. 6 (November 1996): 1599–613. http://dx.doi.org/10.1029/96rs02193.

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7

Kuzenov, Victor V., Sergei V. Ryzhkov, and Aleksey Yu Varaksin. "Computational and Experimental Modeling in Magnetoplasma Aerodynamics and High-Speed Gas and Plasma Flows (A Review)." Aerospace 10, no. 8 (July 25, 2023): 662. http://dx.doi.org/10.3390/aerospace10080662.

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This paper provides an overview of modern research on magnetoplasma methods of influencing gas-dynamic and plasma flows. The main physical mechanisms that control the interaction of plasma discharges with gaseous moving media are indicated. The ways of organizing pulsed energy input, characteristic of plasma aerodynamics, are briefly described: linearly stabilized discharge, magnetoplasma compressor, capillary discharge, laser-microwave action, electron beam action, nanosecond surface barrier discharges, pulsed spark discharges, and nanosecond optical discharges. A description of the physical mechanism of heating the gas-plasma flow at high values of electric fields, which are realized in high-current and nanosecond (ultrafast heating) electric discharges, is performed. Methods for magnetoplasma control of the configuration and gas-dynamic characteristics of shock waves arising in front of promising and advanced aircraft (AA) are described. Approaches to the control of quasi-stationary separated flows, laminar–turbulent transitions, and static and dynamic separation of the boundary layer (for large PA angles of attack) are presented.
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8

SUCHY, K., and C. ALTMAN. "Eigenmode scattering theorems for electromagnetic–acoustic fields in compressible magnetoplasmas with anisotropic pressure." Journal of Plasma Physics 58, no. 2 (August 1997): 247–57. http://dx.doi.org/10.1017/s0022377897005679.

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The electromagnetic–acoustic field in a waveguide filled with a magnetoplasma (or in a stratified magnetoplasma), as well as the corresponding formally adjoint field, are decomposed into eigenmodes. The amplitudes of incoming and outgoing modes for both fields are related by scattering matrices. It is shown that the transposed scattering matrix of one field is the inverse scattering matrix of the other. The fictitious formally adjoint field is temporally mapped into a physical Lorentz-adjoint field, whose scattering matrix is shown to be the transpose of the scattering matrix of the original field.
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9

KHANH, NGUYEN QUOC. "MAGNETOPLASMA OSCILLATIONS OF A TWO-DIMENSIONAL, TWO-COMPONENT PLASMA." Modern Physics Letters B 10, no. 16 (July 10, 1996): 737–44. http://dx.doi.org/10.1142/s0217984996000821.

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We investigate the magnetoplasma excitations in a system comprised of two parallel two-dimensional conducting layers separated by a distance 2d>0. The individual layers are assumed to have, in general, different effective masses, particle densities and charges. The dispersion equations are derived quantum mechanically within the random phase approximation and the spectrum of the long wavelength collective modes is calculated. We also investigate the mutual phase of two-dimensional magnetoplasma oscillations and show that this mutual phase is similar to that in the three-dimensional case and does not depend on the interlayer distance.
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10

ANDREEV, AL A., YA M. BLANTER, and YU E. LOZOVIK. "EXCITATION SPECTRUM OF QUANTUM DOT IN STRONG MAGNETIC FIELD." International Journal of Modern Physics B 09, no. 15 (July 10, 1995): 1843–67. http://dx.doi.org/10.1142/s0217979295000756.

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Microscopic theory of collective excitations of a quantum dot in a strong magnetic field is proposed. A complete analysis of diagrams in the perturbation theory over the Coulomb interaction is performed. The spectrum of low-lying excitations is calculated for the case of a parabolic quantum dot. It is shown to consist of three terms: single-particle drift, magnetoplasma and exciton ones, with the exciton term dominating the magnetoplasma one. In the framework of the semi-classical approach, the case of a non-parabolic quantum dot is also discussed. The experimental manifestations of the effects under investigation are discussed.
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11

Shafranov, Vitalii D. "Methods of describing magnetoplasma systems." Uspekhi Fizicheskih Nauk 159, no. 12 (1989): 721. http://dx.doi.org/10.3367/ufnr.0159.198912f.0721.

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12

Shafranov, Vitalii D. "Methods of describing magnetoplasma systems." Soviet Physics Uspekhi 32, no. 12 (December 31, 1989): 1115. http://dx.doi.org/10.1070/pu1989v032n12abeh002787.

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13

Zaremba, E. "Magnetoplasma excitations in electron rings." Physical Review B 53, no. 16 (April 15, 1996): R10512—R10515. http://dx.doi.org/10.1103/physrevb.53.r10512.

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14

Fisher, L. M., N. M. Makarov, V. E. Vekslerchik, and V. A. Yampol'skii. "Shock magnetoplasma waves in metals." Journal of Physics: Condensed Matter 7, no. 38 (September 18, 1995): 7549–59. http://dx.doi.org/10.1088/0953-8984/7/38/013.

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15

Brandes, T. "Dicke superradiance in a magnetoplasma." Physica B: Condensed Matter 272, no. 1-4 (December 1, 1999): 341–43. http://dx.doi.org/10.1016/s0921-4526(99)00301-4.

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16

SHUKLA, P. K., and M. ROSENBERG. "Drift wave instability in a radially bounded dusty magnetoplasma with parallel ion velocity shear." Journal of Plasma Physics 79, no. 1 (July 17, 2012): 33–35. http://dx.doi.org/10.1017/s0022377812000633.

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AbstractProperties of the coupled dust ion-acoustic drift wave instability in a radially bounded dusty magnetoplasma with an equilibrium sheared parallel ion (SPI) flow are investigated. By using the two-fluid model for the electrons and ions, a wave equation for the low-frequency coupled dust ion-acoustic drift waves in a bounded plasma with stationary charged dust grains is derived. The wave equation admits a linear dispersion relation, which exhibits that the radial boundary affects the growth rate of the coupled ion-acoustic drift wave instability which is excited by the SPI flow. The results should be relevant to dusty magnetoplasma experiments with an SPI flow.
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17

Shukla, P. K., and M. Y. Yu. "Drift vortices in a rotating magnetoplasma." Physics of Fluids 29, no. 5 (1986): 1739. http://dx.doi.org/10.1063/1.865642.

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18

Laurin, J. J., G. A. Morin, and K. G. Balmain. "Sheath wave propagation in a magnetoplasma." Radio Science 24, no. 3 (May 1989): 289–300. http://dx.doi.org/10.1029/rs024i003p00289.

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19

Bruggen-Kerkhof, M. J. Van, L. P. J. Kamp, and F. W. Sluijter. "Wave equations for a relativistic magnetoplasma." Journal of Physics A: Mathematical and General 26, no. 20 (October 21, 1993): 5505–21. http://dx.doi.org/10.1088/0305-4470/26/20/033.

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20

Ye, Z. L., and E. Zaremba. "Magnetoplasma excitations in anharmonic electron dots." Physical Review B 50, no. 23 (December 15, 1994): 17217–29. http://dx.doi.org/10.1103/physrevb.50.17217.

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21

Haque, Q., Arshad M. Mirza, and Shahida Nargis. "Electron-acoustic vortices in multicomponent magnetoplasma." Physics of Plasmas 17, no. 5 (May 2010): 054505. http://dx.doi.org/10.1063/1.3425853.

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22

Shvartsburg, A. "Resonant Joule phenomena in a magnetoplasma." Physics Reports 125, no. 5 (August 1985): 187–252. http://dx.doi.org/10.1016/0370-1573(85)90143-7.

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23

Wendler, L., and V. G. Grigoryan. "Magnetoplasma excitations in quantum-well wires." Physical Review B 49, no. 19 (May 15, 1994): 13607–10. http://dx.doi.org/10.1103/physrevb.49.13607.

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24

Tsintsadze, N. L., H. Hakimi Pajouh, L. N. Tsintsadze, J. T. Mendonca, and P. K. Shukla. "Photon gas in a relativistic magnetoplasma." Physics of Plasmas 7, no. 6 (June 2000): 2348–53. http://dx.doi.org/10.1063/1.874071.

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25

Vranjes, J., and S. Poedts. "Electrostatic waves in bounded dusty magnetoplasma." Physics of Plasmas 11, no. 5 (May 2004): 2178–81. http://dx.doi.org/10.1063/1.1691031.

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26

Kushwaha, M. S. "Helicon Wave Propagation in Semiconductor Magnetoplasma." physica status solidi (b) 130, no. 1 (July 1, 1985): K37—K41. http://dx.doi.org/10.1002/pssb.2221300149.

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27

Dildey, F., and F. R. Kessler. "Magnetoplasma Reflection of Heavily Doped Silicon." physica status solidi (b) 169, no. 1 (January 1, 1992): 141–50. http://dx.doi.org/10.1002/pssb.2221690117.

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28

BARONIA, A., and M. S. TIWARI. "Kinetic Alfvén waves in an inhomogeneous anisotropic magnetoplasma in the presence of an inhomogeneous electric field: particle aspect analysis." Journal of Plasma Physics 63, no. 4 (May 2000): 311–28. http://dx.doi.org/10.1017/s0022377899008272.

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Kinetic Alfvén waves in the presence of an inhomogeneous electric field applied perpendicular to the ambient magnetic field in an anisotropic, inhomogeneous magnetoplasma are investigated. The particle aspect approach is adopted to investigate the trajectories of charged particles in the electromagnetic field of a kinetic Alfvén wave. Expressions are found for the field-aligned current, the perpendicular current, the dispersion relation and the particle energies. The growth rate of the wave is obtained by an energy- conservation method. It is predicted that plasma density inhomogeneity is the main source of instability, and an enhancement of the growth rate by electric field inhomogeneity and temperature anisotropy is found. The dispersion relation and growth rate involve the finite-Larmor-radius effect, electron inertia and the temperature anisotropy of the magnetoplasma. The applicability of the investigation to the auroral acceleration region is discussed.
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29

MISRA, A. P., N. K. GHOSH, and P. K. SHUKLA. "Surface waves in magnetized quantum electron-positron plasmas." Journal of Plasma Physics 76, no. 1 (June 5, 2009): 87–99. http://dx.doi.org/10.1017/s0022377809990055.

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AbstractThe dispersion properties of electrostatic surface waves propagating along the interface between a quantum magnetoplasma composed of electrons and positrons, and vacuum are studied by using a quantum magnetohydrodynamic plasma model. The general dispersion relation for arbitrary orientation of the magnetic field and the propagation vector is derived and analyzed in some special cases of interest (viz. when the magnetic field is directed parallel and perpendicular to the boundary surface). It is found that the quantum effects facilitate the propagation of electrostatic surface modes in a dense magnetoplasma. The effect of the external magnetic field is found to increase the frequency of the quantum surface wave. The existence of a singular wave on the boundary surface is also proved, and its properties are analyzed numerically. It is shown that the new wave characteristics appear due to the Rayleigh type of the wave.
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30

STARODUBTSEV, M., and C. KRAFFT. "Whistler emission through transition radiation by a modulated electron beam spiralling in a magnetoplasma." Journal of Plasma Physics 63, no. 3 (April 2000): 285–95. http://dx.doi.org/10.1017/s0022377899008247.

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Transition radiation from the zone of injection of a modulated electron beam spiralling into a magnetoplasma has been identified as whistler waves propagating quasiparallel to the external magnetic field. The characteristics of the radiation are similar to the emission by localized sources, such as loop antennas and electric dipoles: resonance-cone structures at low plasma densities and energy flow along the external magnetic field at higher densities, with a diverging radiation pattern and with whistler phase velocities inversely proportional to the plasma frequency. These studies should contribute to a wider understanding of the physical processes connected with the injection of charges in a magnetoplasma – either from a gun on board a spacecraft or in a plasma chamber – and thus allow the determination of appropriate radiator characteristics in order to control, to some extent, plasma perturbations and wave emission in the region of the injector.
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31

SINGH, ARVINDER, and NAVPREET SINGH. "Guiding of a laser beam in collisional magnetoplasma channel." Journal of Plasma Physics 78, no. 3 (February 2, 2012): 249–57. http://dx.doi.org/10.1017/s0022377812000049.

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AbstractLaser guiding through an axially non-uniform collisional magnetoplasma channel formed by ionizing laser prepulse has been investigated. Self-defocusing of the ionizing prepulse leads to an axial non-uniform plasma channel. Due to the propagation of second laser beam through such preformed plasma channel, non-uniform heating of electrons takes place on account of non-uniform intensity distribution of laser beam. Non-uniform heating diffuses the electrons away from the axis and thereby enhances the plasma channel. Due to the competition between diffraction and refraction phenomenon through such an axial non-uniform collisional magnetoplasma channel, there is a periodic beam width variation with the distance of propagation. Second order ordinary differential equations for the beam width parameter of prepulse and the guided beam have been set up using the moment theory approach. Effect of axial non-uniformity, intensity of guided beam and magnetic field has been seen on the propagation of the second guided beam in the plasma channel.
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32

SHUKLA, P. K. "Compressional magnetoacoustic waves in a quantum dusty magnetoplasma." Journal of Plasma Physics 74, no. 1 (February 2008): 107–10. http://dx.doi.org/10.1017/s0022377807006642.

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AbstractThe linear dispersion relation for compressional magnetoacoustic waves in a quantum magnetoplasma is derived, taking into account the quantum Bohm potential and the magnetization of electrons due to the electron-1/2 spin effect. It is found that the quantum forces produce the wave dispersion at quantum scales, which depend on the external magnetic field strength.
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33

RICCARDI, C., C. BEVILACQUA, G. CHIODINI, E. SINDONI, and M. FONTANESI. "Modification of electrostatic fluctuations by externally imposed radial electric fields." Journal of Plasma Physics 64, no. 3 (September 2000): 227–33. http://dx.doi.org/10.1017/s0022377800008539.

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This paper concerns experiments on the turbulence of a toroidal magnetoplasma in the presence of a radial electric field. The possibility of reduction of turbulence through the application of an external biasing potential has been evaluated by measuring the electrostatic fluctuations and main plasma parameters.
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34

Kudrin, Alexander V., E. Yu Petrov, George A. Kyriacou, and T. M. Zaboronkova. "INSULATED CYLINDRICAL ANTENNA IN A COLD MAGNETOPLASMA." Progress In Electromagnetics Research 53 (2005): 135–66. http://dx.doi.org/10.2528/pier04090101.

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35

El-Khozondar, Rifa J., Hala J. El-Khozondar, Mohammed M. Shabat, and Alexander W. Koch. "TM Waves Propagation at Magnetoplasma-MTMs Interface." World Journal of Condensed Matter Physics 02, no. 04 (2012): 171–74. http://dx.doi.org/10.4236/wjcmp.2012.24028.

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36

Yang, Jian-Rong, Jie-Jian Mao, Qi-Cheng Wu, Ping Liu, and Li Huang. "Drift wave in strong collisional dusty magnetoplasma." Acta Physica Sinica 69, no. 17 (2020): 175201. http://dx.doi.org/10.7498/aps.69.20200468.

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37

Tovstonog, S. V., I. V. Kukushkin, L. V. Kulik, and V. E. Kirpichev. "Acoustic magnetoplasma excitations in double electron layers." Journal of Experimental and Theoretical Physics Letters 76, no. 8 (October 2002): 511–15. http://dx.doi.org/10.1134/1.1533777.

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38

Salimullah, M., M. Jamil, H. A. Shah, and G. Murtaza. "Jeans instability in a quantum dusty magnetoplasma." Physics of Plasmas 16, no. 1 (January 2009): 014502. http://dx.doi.org/10.1063/1.3070664.

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39

Stenzel, R. L. "Lower‐hybrid turbulence in a nonuniform magnetoplasma." Physics of Fluids B: Plasma Physics 3, no. 9 (September 1991): 2568–81. http://dx.doi.org/10.1063/1.859969.

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40

Masood, W., and A. Mushtaq. "Electron acoustic soliton in a quantum magnetoplasma." Physics of Plasmas 15, no. 2 (February 2008): 022306. http://dx.doi.org/10.1063/1.2841036.

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41

Yang, Jian-Rong, Kui Lv, Lei Xu, Jie-Jian Mao, Xi-Zhong Liu, and Ping Liu. "Drift vortices in inhomogeneous collisional dusty magnetoplasma." Chinese Physics B 26, no. 6 (June 2017): 065202. http://dx.doi.org/10.1088/1674-1056/26/6/065202.

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42

Misra, Amar P., and Chandan Bhowmik. "Nonlinear wave modulation in a quantum magnetoplasma." Physics of Plasmas 14, no. 1 (January 2007): 012309. http://dx.doi.org/10.1063/1.2432052.

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43

Wendler, L., and V. G. Grigoryan. "Erratum: Magnetoplasma excitations in quantum-well wires." Physical Review B 53, no. 15 (April 15, 1996): 10406. http://dx.doi.org/10.1103/physrevb.53.10406.

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44

Yang, Jian-Rong, Bo Wu, Jie-Jian Mao, Ping Liu, and Jian-Yong Wang. "Vortex Street in Homogeneous Dense Dusty Magnetoplasma." Communications in Theoretical Physics 62, no. 6 (December 2014): 871–74. http://dx.doi.org/10.1088/0253-6102/62/6/15.

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45

Shukla, P. K., B. Eliasson, and L. Stenflo. "Alfvénic shock waves in a collisional magnetoplasma." Physics Letters A 375, no. 24 (June 2011): 2371–73. http://dx.doi.org/10.1016/j.physleta.2011.05.006.

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46

Ichiguchi, T. "Vortex cyclotron resonance and Josephson magnetoplasma wave." Physica C: Superconductivity 293, no. 1-4 (December 1997): 105–10. http://dx.doi.org/10.1016/s0921-4534(97)01524-4.

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47

Partoens, B., A. Matulis, and F. M. Peeters. "Magnetoplasma excitations of two vertically coupled dots." Physical Review B 57, no. 20 (May 15, 1998): 13039–49. http://dx.doi.org/10.1103/physrevb.57.13039.

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48

Elmzughi, F. G., N. C. Constantinou, and D. R. Tilley. "The effective-medium theory of magnetoplasma superlattices." Journal of Physics: Condensed Matter 7, no. 2 (January 9, 1995): 315–26. http://dx.doi.org/10.1088/0953-8984/7/2/009.

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49

Dartora, C. A., A. Heilmann, K. Z. Nobrega, V. F. Montagner, E. Burkarter, and Horacio Tertuliano S. Filho. "Radiation pattern from a cold magnetoplasma antenna." Physics of Plasmas 16, no. 7 (July 2009): 073301. http://dx.doi.org/10.1063/1.3167390.

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50

Kalluri, D. K. "Frequency shifting using magnetoplasma medium: flash ionization." IEEE Transactions on Plasma Science 21, no. 1 (1993): 77–81. http://dx.doi.org/10.1109/27.221104.

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