Space-time refraction of space-time wave packets

TL;DR

This paper develops a comprehensive theory of how structured space-time wave packets refract at moving interfaces, enabling control over their velocities and revealing novel regimes like optical push broom and velocity fission.

Contribution

It introduces a general refraction law for space-time wave packets at moving boundaries, unifying static and dynamic cases and enabling new light control applications.

Findings

Refraction laws for various wave packets at moving interfaces.

Identification of regimes like optical push broom and velocity fission.

Potential applications in reconfigurable optical devices and emulation of physical phenomena.

Abstract

Space-time modulation of refractive index can produce synthetically moving interfaces with arbitrary apparent velocities, including superluminal motion, offering new ways to control light in dynamic media. On the other hand, space-time wave packets are structured waves whose spatio-temporal spectra lie on tilted space-time planes, so their group velocity can be programmed, including superluminal values, even in a uniform medium. Here we develop a general theory of space-time refraction for such structured waves at a planar moving interface and show how a single boundary reshapes their velocity content. By identifying the invariants of a translating boundary, we obtain refraction laws for baseband, X-wave, and sideband packets that apply for arbitrary interface velocities and connect smoothly to static and purely temporal limits. These laws reveal regimes of "space-time anomalous optical push broom," where a moving interface compresses a wide range of incident velocities into a narrow transmitted band, and "velocity spectral optical fission," where an incident X-wave splits into two propagation-invariant branches with distinct velocities. The combined freedom to prepare waves with superluminal group velocity and to prescribe equally unconstrained interface speeds points toward reconfigurable time gating, optical buffering, velocity multiplexing, and controlled emission in moving media, and provides a route to photonic settings capable of emulating dynamical effects traditionally associated with gravitational or quantum processes.