100 research outputs found
Compton scattering of twisted light: angular distribution and polarization of scattered photons
Compton scattering of twisted photons is investigated within a
non-relativistic framework using first-order perturbation theory. We formulate
the problem in the density matrix theory, which enables one to gain new
insights into scattering processes of twisted particles by exploiting the
symmetries of the system. In particular, we analyze how the angular
distribution and polarization of the scattered photons are affected by the
parameters of the initial beam such as the opening angle and the projection of
orbital angular momentum. We present analytical and numerical results for the
angular distribution and the polarization of Compton scattered photons for
initially twisted light and compare them with the standard case of plane-wave
light
Spectral caustics in laser assisted Breit-Wheeler process
Electron-positron pair production by the Breit-Wheeler process embedded in a
strong laser pulse is analyzed. The transverse momentum spectrum displays
prominent peaks which are interpreted as caustics, the positions of which are
accessible by the stationary phases. Examples are given for the superposition
of an XFEL beam with an optical high-intensity laser beam. Such a configuration
is available, e.g., at LCLS at present and at European XFEL in near future. It
requires a counter propagating probe photon beam with high energy which can be
generated by synchronized inverse Compton backscattering
Backreaction on background fields: A coherent state approach
There are many situations in which a strong electromagnetic field may be
approximated as a fixed background. Going beyond this approximation, i.e.
accounting for the back-reaction of quantum process on the field, is however
challenging. Here we develop an approach to this problem which is a
straightforward extension of background field methods. The approach follows
from the observation that scattering in an on-shell background is equivalent to
scattering between coherent states; we show that by deforming these states one
can model back-reaction. Focussing on intense laser-matter interactions, we
provide examples which model beam depletion and, furthermore, introduce an
extremisation principle with which to determine the level of depletion in a
given scattering process.Comment: 16 pages, 6 pdf figure
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