Optical Spin Effects Induced by Phase Conjugation at a Space-Time Interface
Abstract
Electromagnetic temporal boundaries, emerging when the constitutive parameters of a medium undergo abrupt temporal variations, have garnered significant interest for their role in facilitating unconventional wave phenomena and enabling sophisticated field manipulations. A key manifestation is temporal reflection in an unbounded spatial domain, where a sudden temporal discontinuity induces phase-conjugated backward waves alongside anomalous spin conversion. This study explores distinctive spin-conversion dynamics at a time-dependent spatial interface governed by Lorentz-type dispersion, in which the plasma frequency undergoes rapid modulation over time. The interaction of a circularly polarized wave with a space-time interface excites electromagnetic signals at the system's natural resonance, allowing precise control over polarization states. The scattered field stems from the combined influence of temporal and spatial boundaries, yielding a superposition of the original incident wave's polarization and its phase-conjugated counterpart.
Cite
@article{arxiv.2510.21235,
title = {Optical Spin Effects Induced by Phase Conjugation at a Space-Time Interface},
author = {Carlo Rizza and Alessandra Contestabile and Maria Antonietta Vincenti and Giuseppe Castaldi and Marcello Ferrera and Alessandro Stroppa and Michael Scalora and Vincenzo Galdi},
journal= {arXiv preprint arXiv:2510.21235},
year = {2025}
}
Comments
12 pages, 5 figures. Accepted for publication in Small (Wiley)