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Spectral-angular characteristics of the radiation of a charged particle in the Redmond field
Based on the solution of the equation of motion of a charge in an electromagnetic field, the classical theory of radiation of a relativistic charged particle linearly accelerated by a high-intensity laser pulse in the presence of a static component of the magnetic field is constructed. Solutions obtained by Kopytov G.F. and Pogorelov A.V., were used to study the spectral-angular characteristics of the radiation of a charged particle in a combination of the field of a plane monochromatic electromagnetic wave and a constant magnetic field, the so-called Redmond field. According to the calculated formulas for the radiation intensity of particles in the Redmond field, graphs of the dependence on the magnitude of the magnetic field, phase and phase-angular distributions are plotted. The Fourier transform of the intensity of the electric field of the radiation and the spectral density of the radiation of the particle in the case of linear polarization of the wave is obtained. Keywords: Redmond field, spectral-angular characteristics, charged particle, Lawson-Woodward theorem, superpower laser radiation.
- N.S. Akintsov, G.F. Kopytov, A.A. Martynov, Nauchno-tekhicheskie vedomosti SPbGPU. Fiziko-matematicheskie nauki, 230 (4), 150 (2015), (in Russian). DOI: 10.5862/JPM.230.14
- T. Tajima, J. Dawson. Phys. Rev. Lett., 43 (4), 267 (1979). DOI: 10.1103/PhysRevLett.43.267
- Y. Wu, J. Hua, Z. Zhou, J. Zhang, S. Liu, B. Peng, Y. Fang, X. Ning, Z. Nie, F. Li, C. Zhang, C.-H. Pai, Y. Du, W. Lu, W.B. Mori, C. Joshi. Nat. Phys., 17, 801 (2021). DOI: 10.1038/s41567-021-01202-6
- L.J. Wong, K.-H. Hong, S. Carbajo, A. Fallahi, P. Piot, M. Soljav cic, J.D. Joannopoulos, F.X. Kartner, I. Kaminer. Sci. Rep., 7 (1), 11159 (2017). DOI: 10.1038/s41598-017-11547-9
- P.M. Woodward, J.D. Lawson. J. Institution of Electrical Engineers --- Part III: Radio and Communication Engineering, 95 (37), 363 (1948). DOI: 10.1049/ji-3-2.1948.0094
- P.J. Redmond. J. Math. Phys., 6, 1163 (1965). DOI: 10.1063/1.1704385
- V.G. Bagrov, V.A. Bordovitsyn. Zh. Vychisl. Mat. Mat. Fiz., 8 (3), 691 (1968). [V.G. Bagrov, V.A. Bordovitsyn, Comput. Math. Math. Phys., 8 (3), 274 (1968) DOI: 10.1016/0041- 5553(68)90082-7]
- A. Orefice. II Nuovo Cimento B, 63 (2), 638 (1969). DOI: 10.1007/BF02710713
- E.M. Boldyrev. J. Techn. Phys., 69 (5), 106 (1999)
- V.V. Apollonov, M.V. Fedorov, A.M. Prokhorov, A.G. Suzdal'tsev. IEEE J. Quantum Electronics, 28 (1), 265 (1992). DOI: 10.1109/3.119522
- B.-L. Qian. Physics of Plasmas, 7, 537 (2000). DOI: 10.1063/1.873839
- A. Dubik. Laser and Particle Beams, 18 (2), 341 (2000). DOI: 10.1017/S0263034600182254
- G.F. Kopytov, A.A. Martynov, N.S. Akintsov, Nauchno-tekhicheskie vedomosti SPbGPU. Fiziko-matematicheskie nauki, 206 (4), 55 (2014), (in Russian)
- G.F. Kopytov, A.V. Pogorelov, Nauchno-tekhicheskie vedomosti SPbGPU. Fiziko-matematicheskie nauki, 146 (2), 112[A (2012), (in Russian)
- V. Zhukovsky. Symmetry, 12 (8), 1367 (2020). DOI: 10.3390/sym12081367
- V.A. Buts, A.G. Zagorodny. Physics of Plasmas, 28 (2), 022311 (2021). DOI: 10.1063/5.0037808
- Yu.A. Bashmakov, D.F. Alferov. J. technical physics, 55 (5), 829 (1985)
- A.V. Bashinov, A.A. Gonoskov, A.V. Kim, M. Marklund, G. Mourou, A.M. Sergeev. Quantum Electronics, 43 (4), 291 (2013). DOI: 10.1070/QE2013v043n04ABEH015101
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