Probing dynamics of time-varying media: Beyond abrupt temporal interfaces

Abstract

This work investigates the effects of time-varying media, where optical properties change over time, on electromagnetic wave propagation, focusing on plane waves and free-electron evanescent waves. We introduce a switching parameter, τ, to model ultrafast switching in the femtosecond to nanosecond range. For plane-wave incidence at angular frequency ω0, we derive a generalized expression for the backward-to-forward flux ratio as a function of ω0 and τ, aligning with recent experimental data and providing a unified interpretation framework. For free-electron incidence, we observe intensity saturation in temporal transition radiation at Imax for τ ≤ τ0, with both Imax and τ0 depending on electron speed. These results highlight the importance of precise τ control in experiments to probe time-varying media effectively.