Abstract
We study nonlinear trident in laser pulses in the high-energy limit, where the initial electron experiences, in its rest frame, an electromagnetic field strength above Schwinger's critical field. At lower energies the dominant contribution comes from the "two-step" part, but in the high-energy limit the dominant contribution comes instead from the one-step term. We obtain new approximations that explain the relation between the high-energy limit of trident and pair production by a Coulomb field, as well as the role of the Weizs\"acker-Williams approximation and why it does not agree with the high-$\chi$ limit of the locally-constant-field approximation. We also show that the next-to-leading order in the large-$a_0$ expansion is, in the high-energy limit, nonlocal and is numerically very important even for quite large $a_0$. We show that the small-$a_0$ perturbation series has a finite radius of convergence, but using Pad\'e-conformal methods we obtain resummations that go beyond the radius of convergence and have a large numerical overlap with the large-$a_0$ approximation. We use Borel-Pad\'e-conformal methods to resum the small-$\chi$ expansion and obtain a high precision up to very large $\chi$. We also use newer resummation methods based on hypergeometric/Meijer-G and confluent hypergeometric functions.
Highlights
Quantum electrodynamics in strong laser fields is usually studied by treating the interaction with the quantized photon field in a standard perturbation expansion in α 1⁄4 e2=ð4πÞ, but with a Volkov/Furry picture treatment of the strong field
We obtain new approximations that explain the relation between the high-energy limit of trident and pair production by a Coulomb field, as well as the role of the Weizsäcker-Williams approximation and why it does not agree with the high-χ limit of the locally-constantfield approximation
We show that the next-to-leading order in the large-a0 expansion is, in the highenergy limit, nonlocal and is numerically very important even for quite large a0
Summary
Quantum electrodynamics in strong laser fields is usually studied by treating the interaction with the quantized photon field in a standard perturbation expansion in α 1⁄4 e2=ð4πÞ, but with a Volkov/Furry picture treatment of the strong field. We compare the high-energy limit of trident with pair production by a Coulomb field in a plane wave To do this we generalize our results in [1] to a process where the initial electron is replaced by another particle, e.g., a muon, which has the same charge but different mass. For trident, where the emitted photon decays into a pair, one finds that the probability is largest when the initial electron keeps almost all of its momentum and only gives a small fraction to the emitted photon and the produced pair This low-momentum transfer has an important impact on the behavior of the high-energy limit of trident compared to the first-order processes [5,6].
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