Quantum backreaction in laser-driven plasma
Abstract
We present a new approach for investigating quantum effects in laser-driven plasma. Unlike the modelling strategies underpinning particle-in-cell codes that include the effects of quantum electrodynamics, our new field theory incorporates multi-particle effects from the outset. Our approach is based on the path-integral quantisation of a classical bi-scalar field theory describing the behaviour of a laser pulse propagating through an underdense plasma. Results established in the context of quantum field theory on curved spacetime are used to derive a non-linear, non-local, effective field theory that describes the evolution of the laser-driven plasma due to quantum fluctuations. As the first application of our new theory, we explore the behaviour of perturbations to fields describing a uniform, monochromatic, laser beam propagating through a uniform plasma. Our results suggest that quantum fluctuations could play a significant role in the evolution of an underdense plasma driven by an x-ray laser pulse.
Cite
@article{arxiv.1906.09606,
title = {Quantum backreaction in laser-driven plasma},
author = {A. Conroy and C. Fiedler and A. Noble and D. A. Burton},
journal= {arXiv preprint arXiv:1906.09606},
year = {2020}
}
Comments
18 pages. Several corrections have been made. The first and last sections have been substantially rewritten. An appendix has been included