Author:
Ong J. F.,Berceanu A. C.,Grigoriadis A.,Andrianaki G.,Dimitriou V.,Tatarakis M.,Papadogiannis N. A.,Benis E. P.
Abstract
AbstractLaser plasma-based accelerators provide an excellent source of collimated, bright, and adequately coherent betatron-type x-ray pulses with potential applications in science and industry. So far the laser plasma-based betatron radiation has been described within the concept of classical Liénard–Wiechert potentials incorporated in particle-in-cell simulations, a computing power-demanding approach, especially for the case of multi-petawatt lasers. In this work, we describe the laser plasma-based generation of betatron radiation at the most fundamental level of quantum mechanics. In our approach, photon emission from the relativistic electrons in the plasma bubble is described within a nonlinear quantum electrodynamics (QED) framework. The reported QED-based betatron radiation results are in excellent agreement with similar results using Liénard–Wiechert potentials, as well as in very good agreement with betatron radiation measurements, obtained with multi-10-TW lasers interacting with He and multielectron N$$_2$$
2
gas targets. Furthermore, our QED approach results in a dramatic reduction of the computational runtime demands, making it a favorable tool for designing betatron radiation experiments, especially in multi-petawatt laser facilities.
Funder
Extreme Light Infrastructure-Nuclear Physics (ELI-NP) Phase II
Ministry of Research, Innovation and Digitalization
Publisher
Springer Science and Business Media LLC