Anomalous Effects in Single-slit Diffraction of Light at Relativistic Intensities

TL;DR

This paper explores novel optical phenomena in high-order harmonic generation during single-slit diffraction of relativistic laser pulses, revealing anomalous polarization, spectrum variation, and beam deflection through simulations and a new theoretical model.

Contribution

It introduces a comprehensive kinetic simulation study and a new theoretical framework to explain complex electron dynamics and resulting harmonic effects at relativistic intensities.

Findings

Harmonic beams exhibit anomalous polarization orthogonal to the driver.

Harmonic spectrum varies with incident laser polarization.

Transmitted light is deflected, creating a tilted harmonic pattern.

Abstract

High-order harmonic generation via single-slit diffraction of relativistic laser pulses is investigated. Using fully kinetic 2D and 3D particle-in-cell simulations, we show that interesting optical phenomena emerge, including the generation of harmonic beams that are anomalously polarized orthongal to the driver, harmonic spectrum variation depending on the incident laser polarization, and a deflection of transmitted lights that leads to a tilted harmonic intensity pattern. It is shown these anomalous effects are associated with complex peripheral electron dynamics on the plasma vacuum interface. To account for these effects, a new theoretical model is developed to calculate harmonic fields from arbitrary 2D electron motion within the diffraction plane, the results agree well with the simulations. Our model indicates that the optical properties of the harmonic beams are determined by the 2D in-plane electron motion, which can be leveraged to provide immense opportunities for manipulating light-matter interaction at relativistic intensities.