Observation of full momentum bandgap in photonic time crystals

TL;DR

This paper reports the first experimental observation of full momentum bandgaps in microwave photonic time crystals, demonstrating enhanced control over microwave fields and paving the way for optical frequency applications.

Contribution

It provides the first experimental demonstration of a full momentum bandgap in microwave photonic time crystals, confirming theoretical predictions and showcasing practical modulation techniques.

Findings

Achieved a full momentum bandgap spanning the entire momentum space.

Enhanced the bandgap width using resonance effects in microwave metamaterials.

Enabled arbitrary spatial localization and temporal amplification of microwave fields.

Abstract

The hallmark feature of photonic time crystals (PTCs) is the momentum bandgap, yet opening such a gap is extremely challenging, as it demands strong and rapid temporal modulation of the material properties. Recent theoretical advances have shown that resonance effects can substantially expand the momentum bandgap, and even give rise to a full (infinite) momentum bandgap spanning the entire momentum space. Despite these predictions, a full momentum bandgap has yet to be observed experimentally. Here, we report the first experimental observation of full momentum bandgaps in a microwave PTC. By enhancing the resonant effect, we demonstrate that the momentum bandgap can be drastically widened in a dynamically modulated microwave surface plasmon transmission-line metamaterial, leading to tighter spatiotemporal field confinement and greater robustness against temporal disorder. Remarkably, using a dynamically modulated microwave coupled resonator metamaterial characterized by coupled-resonator optical waveguide dispersion, we achieve a full momentum bandgap spanning the entire momentum space, thereby enabling arbitrary spatial localization and temporal amplification of microwave fields. Our findings establish a unified experimental framework for expanding momentum bandgaps up to an infinite extent with minimal requirements on modulation strength and speed, thus paving a viable route toward the first experimental realization of PTCs at optical frequencies.