Subject Areas : Journal of Optoelectronical Nanostructures
Delaram Karimi Moghadam 1 , Ghahraman Solookinejad 2
1 - Department of physics, Malayer Branch, Islamic Azad University, Malayer, Iran
2 - Marvdasht Branch Islamic Azad University, Marvdasht, Iran
Keywords:
Abstract :
[1] Z.A. Moldabekov, M. Bonitz, T. Ramazanov. Impact of single particle oscillations on screening of a test charge. Phys Plasmas. 25 (2018, Jun.) 031903.
[2] A. Abdikian. Modulational instability of ion-acoustic waves in magnetoplasma with pressure of relativistic electrons. Phys Plasmas. 24 (2017, May.) 052123.
[3] M. Ahmad, M. Farooq, A. Ullah. On a semiclassical model for damped dust ion-acoustic solitons with analysis of quantum electron exchange-correlation potential. Phys Plasmas. 27 (2020, Jan.) 023704.
[4] N. Sadiq, M. Ahmad. Kinetic Alfvén soliton structure with exchange-correlation potential in quantum plasma. Plasma Research Express. 2 (2020, Feb.) 015007.
[5] M. Sheng-Hong, X. Ju-Kui. Reduced and n-Type Doped TiO2: Nature of Ti3+ Species. Phys Scr. 84 (2011, Sep.) 20543–20552.
[6] A. Abdikian. The effects of exchange–correlation on high-frequency electrostatic surface wave in magnetized quantum plasma through a porous medium. Indian Journal of Physics. 91 (2017, Apr.) 1127–1133.
[7] S. Hussain, S. Mahmood. Chaos Soliton Fract. 106, 266 (2018, Jan.) 1-378.
[8] J. Goswami, S. Chandra, J. Sarkar, D. Bhattacharjee, D. Nandi, B. Ghosh. Energy Exchange Due to Resonant Interactions between the Fundamental and Higher Harmonic of Nonlinear Surface Waves in Quantum Plasma. Sustainable Humanosphere. 16 (1) (2020, Jan) 910-916.
[9] N. Rani, M. Yadav, Y. Mathur. Generation of Soliton, Cnoidal, and Periodic Waves During Pumping GaAs by an Electron Beam. Phys Lett A. 384 (2020, Apr.) 18-25.
[10] K. Jensen, D. Shiffler, J. Lebowitz, M. Cahay, J. Petillo. Analytic Wigner distribution function for tunneling and trajectory models. Appl Phys. 125 (2019, Feb.) 114303.
[11] A. Abdikian, Z. Ehsan. Propagation of electrostatic surface waves in a thin degenerate plasma film with electron exchange–correlation effects. Phys Lett A. 381(2017, Sep.) 2939-2943.
[12] F. Haas, L.G. Garcia, J. Goedert, G. Manfredi. Quantum ion-acoustic waves. Phys Plasmas. 10 (2003, July.) 3858.
68 * Journal of Optoelectronical Nanostructures Summer 2020 / Vol. 5, No. 3
[13] P.K. Shukla, B. Eliasson. Formation and Dynamics of Dark Solitons and Vortices in Quantum Electron Plasmas. Phys Rev Lett. 96 (2006, Jun.) 245001.
[14] M. Bagheri, A. Abdikian. Space-charge waves in magnetized and collisional quantum plasma columns confined in carbon nanotubes. Phys Plasmas. 21 (2014, Apr.) 042506.
[15] C.L. Gardner, C. Ringhofer. Smooth quantum potential for the hydrodynamic model. Phys Rev E. 53 (1996, Jan.) 157.
[16] S. Chandra, B. Ghosh. Modulational instability of electron-acoustic waves in relativistically degenerate quantum plasma. Astrophys Space Sci. 342 (2012, July.) 417–424.
[17] S. Khan, A. Mushtaq. Linear and nonlinear dust ion acoustic waves in ultracold quantum dusty plasmas. Phys Plasmas. 14 (2007, June.) 083703.
[18] B. Sahu, R. Roychoudhury. Cylindrical and spherical quantum ion acoustic waves. Phys Plasmas. 14 (2007, Nov.) 012304.
[19] K. Mebrouk, L.A. Gougam, M. Tribeche. Implication of the Electron Exchange-Correlation on Fully Nonlinear Quantum Dust Ion-Acoustic Solitons. Common Theo Phys. 65 (2016, Jun.) 73.
[20] A. Abdikian. Cylindrical fast magnetosonic solitary waves in quantum degenerate electron-positron-ion plasma. Phys Plasmas. 25 (2018, Feb.) 022308.
[21] B. Sahu, R. Roychoudhury. Electron acoustic solitons in a relativistic plasma with nonthermal electrons. Phys Plasmas. 13 (2006, May.) 072302.
[22] B. Ghosh, S. Chandra, S. Paul. Amplitude modulation of electron plasma waves in a quantum plasma. Phys Plasmas. 18 (2011, Dec.) 012106.
[23] F. Haas. A magnetohydrodynamic model for quantum plasmas. Phys Plasmas. 12 (2005, May.) 062117.
[24] F. Haas, G. Manfredi, M. Feix. Multistream model for quantum plasmas. Phys Rev E. 62 (2000, Aug.) 2763.
[25] G.A. Hoshoudy. Propagation of TM-surface waves on semi-bounded quantum plasma through porous medium. Indian J Phys. 90 (2016, Sep.) 477.
[26] S. Chandra, S.N. Paul, B. Ghosh. Linear and non-linear propagation of electron plasma waves in quantum plasma. Indian J Pure Appl Phys. 50 (2012, May.) 314.
Implication of Quantum Effects on Non-Linear Propagation of Electron Plasma Solitons * 69
[27] H. Demiray, A. Abdikian. Modulational instability of acoustic waves in a dusty plasma with nonthermal electrons and trapped ions. Chaos Soliton Fact. 121 (2019, Apr.) 50-58.
[28]. A. Abdikian, Z. Safi. Finding Electrostatics modes in Metal Thin Films by using of Quantum Hydrodynamic Model. Jopn 1(3) (2016, Autumn.) 43-50.
[29]. A. Abdikian, GH. Solookinejad, Z. Safi. Electrostatics Modes in Mono-Layered Graphene. Jopn 1(2), (2016, Summer.) 1-8.
[30]. Kh. Zarei, GH. Solookinejad, M. Jabbari. Investigating the Properties of an Optical Waveguide Based on Photonic Crystal with Point Defect and Lattice Constant Perturbation. Jopn 1(1) (2016, Spring.) 65-80.
[31]. S. Fotoohi, S. Haji Nasiri. Vacancy Defects Induced Magnetism in Armchair Graphdiyne Nanoribbon. Jopn 4(4) (2019, Autumn.) 15-38.
[32]. A. Farmani, A. Mir, H. Emami nejad. Numerical Modeling of a Metamaterial Biosensor for Cancer Tissues Detection. Jopn 5(1) (2020, Winter.) 1-18.
