Quantum vacuum signatures in multi-color laser pulse collisions
Holger Gies, Felix Karbstein, Leonhard Klar
TL;DR
This paper investigates quantum vacuum nonlinearities in multi-color laser pulse collisions, identifying promising signal photon channels and proposing methods to enhance photon yield through sum and difference frequency generation.
Contribution
It introduces a strategy to trace vacuum-fluctuation-mediated processes and optimize signal photon production in multi-pulse laser collisions.
Findings
Identification of key signal photon channels in multi-pulse collisions
Demonstration of enhanced photon yield via frequency mixing techniques
Analysis of quantum vacuum nonlinearities in realistic laser configurations
Abstract
Quantum vacuum fluctuations give rise to effective non-linear interactions between electromagnetic fields. A prominent signature of quantum vacuum nonlinearities driven by macroscopic fields are signal photons differing in characteristic properties such as frequency, propagation direction and polarization from the driving fields. We devise a strategy for the efficient tracing of the various vacuum-fluctuation-mediated interaction processes in order to identify the most prospective signal photon channels. As an example, we study the collision of up to four optical laser pulses and pay attention to sum and difference frequency generation. We demonstrate how this information can be used to enhance the signal photon yield in laser pulse collisions for a given total laser energy.
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