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Accurate evaluation of the conditions for generation of quantum effects in relativistic interactions between laser and electron beams

Published online by Cambridge University Press:  18 September 2018

Alexandru Popa
Alexandru Popa*
Affiliation:
National Institute for Laser, Plasma and Radiation Physics, Laser Department, P.O. Box MG-36, Bucharest, Romania 077125
*
Author for correspondence: Alexandru Popa, National Institute for Laser, Plasma and Radiation Physics, Laser Department, P.O. Box MG-36, Bucharest, Romania 077125. E-mail: [email protected]
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Abstract

The quantum behavior of the system composed of an electron in an electromagnetic field is described by the Dirac equation, whose solution is a wave function represented by a column matrix with four components. We prove, without using any approximation, that these components can be put in a form which reveals directly the values of the electron energy, laser beam intensity, or amplitude of the electric field intensity, for which the quantum electrodynamics effects are generated. Our results are in good agreement with the experimental data reported in the literature. We prove that the four components of the wave function verify the continuity equation of quantum electrodynamics. Our treatment is in good agreement with the Compton relation. We show that the interaction of electrons with laser beams could be modeled using classical approaches regardless of the laser beam intensity as long as the electrons are non-relativistic, in agreement with published experimental data.

Keywords

Electron beamslaser beamspartial differential equationsrelativistic electrodynamics
Type
Research Article
Information
Laser and Particle Beams , Volume 36 , Issue 3 , September 2018 , pp. 323 - 334
Copyright
Copyright © Cambridge University Press 2018 

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References

Bamber, C, Boege, SJ, Koffas, T, Kotseroglou, T, Melissinos, AC, Meyerhofer, DD, Reis, DA, Ragg, W, Bula, C, McDonald, KT, Prebys, EJ, Burke, DL, Field, RC, Horton-Smith, G, Spencer, JE, Walz, D, Berridge, SC, Bugg, WM, Shmakov, K and Weidemann, AW (1999) Studies of nonlinear QED in collisions of 46.6 GeV electrons with intense laser pulses. Physical Review D 60, 092004.Google Scholar
Boca, M and Florescu, V (2009) Nonlinear Compton scattering with a laser pulse. Physical Review A 80, 053403.Google Scholar
Brown, LS and Kibble, WB (1964) Interaction of intense laser beams with electrons. Physics Reviews 133, A705A719.Google Scholar
Bula, C, McDonald, KT, Prebys, EJ, Bamber, C, Boege, S, Kotseroglou, T, Melissinos, AC, Meyerhofer, DD, Ragg, W, Burke, DL, Field, RC, Horton-Smith, G, Odian, AC, Spencer, JE, Walz, D, Berridge, SC, Bugg, WM, Shmakov, K and Weidemann, AW (1996) Observation of nonlinear effects in Compton scattering. Physical Review Letters 76, 31163119.Google Scholar
Burke, DL, Field, RC, Horton-Smith, G, Spencer, JE, Walz, D, Berridge, SC, Bugg, WM, Shmakov, K, Weidemann, AK, Bula, C, McDonald, KT, Prebys, EJ, Bamber, C, Boege, SJ, Koffas, T, Kotseroglou, T, Melissinos, AC, Meyerhofer, DD, Reis, DA and Ragg, W (1997) Positron production in multiphoton light-by-light scattering. Physical Review Letters 79, 16261629.Google Scholar
Dirac, PAM (1958) The Principles of Quantum Mechanics. London: Oxford Clarendon Press.Google Scholar
Harvey, C, Heinzl, T and Ilderton, A (2009) Signatures of high-intensity Compton scattering. Physical Review A 79, 063407.Google Scholar
Jackson, JD (1999) Classical Electrodynamics. New York: Wiley.Google Scholar
Kirsebom, K and Kaminski, JZ (2012) Compton process in intense short laser pulses. Physical Review A 85, 062102.Google Scholar
Kirsebom, K, Mikkelsen, U, Uggerhoj, E, Elsener, K, Ballestrero, S, Sona, P and Vilakazi, ZZ (2001) First measurements of the unique influence of spin on the energy loss of ultrarelativistic electrons in strong electromagnetic fields. Physical Review Letters 87, 054801.Google Scholar
Landau, LD and Lifshitz, EM (1959) The Classical Theory of Fields. London: Pergamon Press.Google Scholar
Messiah, A (1962) Quantum Mechanics, Vol. 2. Amsterdam: North-Holland.Google Scholar
Panek, P, Kaminski, JZ and Ehlotzki, F (2002) Laser-induced Compton scattering at relativistically high radiation powers. Physical Review A 65, 022712.Google Scholar
Popa, A (2011) Periodicity property of relativistic Thomson scattering with application to exact calculations of angular and spectral distributions of the scattered field. Physical Review A 84, 023824.Google Scholar
Popa, A (2012) Polarization effects in collisions between very intense laser beams and relativistic electrons. Laser and Particle Beams 30, 591603.Google Scholar
Popa, A (2014a) Accurate calculation of radiation damping parameters in the interaction between very intense laser beams and relativistic electron beams. Laser and Particle Beams 32, 477486.Google Scholar
Popa, A (2014b) Theory of Quantum and Classical Connections in Modeling Atomic, Molecular and Electrodynamic Systems. Amsterdam, Boston: Elsevier, Academic Press.Google Scholar
Popa, A (2014c) Applications of Quantum and Classical Connections in Modeling Atomic, Molecular and Electrodynamic Systems. Amsterdam, Boston: Elsevier, Academic Press.Google Scholar
Volkov, DM (1935) Uber eine Klasse von Losungen der Diracshen Gleichung. Zeitschrift für Physik 94, 250260.Google Scholar
Weinberg, S (1995) The Quantum Theory of Fields, Vol. 1. Cambridge: Cambridge University Press.Google Scholar