Rise and fall of laser-intensity effects in spectrally resolved Compton process

Abstract

The spectrally resolved differential cross section of Compton scattering, d σ / d ω' ω' = const, rises from small towards larger laser intensity parameter , reaches a maximum, and falls towards the asymptotic strong-field region. Expressed by invariant quantities: d σ /du u = const rises from small towards larger values of , reaches a maximum at max = 49 K u m2 / k · p, K = O (1), and falls at > max like -3/2 (- 2 u m23 \, k · p ) at u 1. [The quantity u is the Ritus variable related to the light-front momentum-fraction s = (1 + u)/u = k · k' / k · p of the emitted photon (four-momentum k', frequency ω'), and k · p/m2 quantifies the invariant energy in the entrance channel of electron (four-momentum p, mass m) and laser (four-wave vector k).] Such a behavior of a differential observable is to be contrasted with the laser intensity dependence of the total probability, = k · p/m2, ∞ P α 2/3 m2 / k · p, which is governed by the soft spectral part. We combine the hard-photon yield from Compton with the seeded Breit-Wheeler pair production in a folding model and obtain a rapidly increasing e+ e- pair number at 4. Laser bandwidth effects are quantified in the weak-field limit of the related trident pair production.