Kinematics and Selection Rules for Light-by-Light Scattering in a Strong Magnetic Field
Abstract
:1. Introduction
2. Kinematics of Scattering a Photon by a Photon
2.1. Eigen-Value Problem for the Polarization Tensor, Polarization, and the Dispersion of Eigen-Modes
2.1.1. Polarization of Eigen-Modes
2.1.2. Dispersion of Eigen-Modes in the Heisenberg–Euler Approximation
2.2. Conservation Laws and Selection Rules
2.2.1. Perpendicular Incidence
2.2.2. Parallel Incidence
2.3. Quantitative Side of the Wave-Length Shifts
2.3.1. Perpendicular Incidence
2.3.2. Parallel Incidence
3. Conclusions
Funding
Acknowledgments
Conflicts of Interest
References
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1. | except, perhaps, the Schwinger effect of the pair production from the vacuum by a strong constant electric field. |
2. | It is interesting to note that, when the nonlinearity is determined by the Heisenberg–Euler Lagrangian, a traveling-wave solution of nonlinear Maxwell equations is provided by a dispersion law that involves a dependence on the amplitudes of the traveling wave [19]. This is, certainly, not our case, since we deal with the propagation of small-amplitude waves governed by equations linearized near an external field. |
3. | |
4. | These convexity properties are certainly respected by the HE approximation resulting in Equations (15) and (16). The third condition following from the causality principle, can be violated for unrealistic exponentially strong fields (in accord with Equation (30) below) as a manifestation of the intrinsic trouble of QED known as the lack of asymptotic freedom. |
5. | More generally, the dispersion curve for Mode 3 goes higher than that for Mode 2 because the lowest energy threshold, where the photon may create an electron-positron pair, is for Mode 3 higher: one particle out of the two created by the photon of this mode belongs to an excited Landau level, whereas the Mode 2 photon may create a pair of particles, both in the ground Landau states. The point is that the polarization tensor is infinite at each of the thresholds; hence, each threshold strongly affects the dispersion law; see [21,22] for further explanations. |
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Shabad, A. Kinematics and Selection Rules for Light-by-Light Scattering in a Strong Magnetic Field. Universe 2020, 6, 211. https://doi.org/10.3390/universe6110211
Shabad A. Kinematics and Selection Rules for Light-by-Light Scattering in a Strong Magnetic Field. Universe. 2020; 6(11):211. https://doi.org/10.3390/universe6110211
Chicago/Turabian StyleShabad, Anatoly. 2020. "Kinematics and Selection Rules for Light-by-Light Scattering in a Strong Magnetic Field" Universe 6, no. 11: 211. https://doi.org/10.3390/universe6110211
APA StyleShabad, A. (2020). Kinematics and Selection Rules for Light-by-Light Scattering in a Strong Magnetic Field. Universe, 6(11), 211. https://doi.org/10.3390/universe6110211