Pseudounitary Floquet scattering matrix for wave-front shaping in time-periodic photonic media

TL;DR

This paper introduces a pseudounitary Floquet scattering matrix for wave control in time-periodic media, enabling wavefront shaping and pulse optimization in dynamic photonic systems.

Contribution

It formulates a pseudounitary Floquet scattering matrix that accurately describes wave scattering in time-periodic media and extends wavefront-shaping techniques to these systems.

Findings

The Floquet scattering matrix satisfies a pseudounitary relation.

Eigenstates of the Floquet Wigner-Smith matrix are optimally shaped light pulses.

The approach enables optical micromanipulation in time-varying media.

Abstract

The physics of waves in time-varying media provides numerous opportunities for wave control that are unattainable with static media. In particular, Floquet systems with a periodic time modulation are currently of considerable interest. Here, we demonstrate how the scattering properties of a finite Floquet medium can be correctly described by a static Floquet scattering matrix, which satisfies a pseudounitary relation. This algebraic property is a consequence of the conservation of wave action for which we formulate here a continuity equation. Using this Floquet scattering matrix, we further demonstrate how it can be used to transfer concepts for wavefront-shaping based on the Wigner-Smith operator from static to Floquet systems. The eigenstates of the corresponding Floquet Wigner-Smith matrix are shown to be light pulses that are optimally shaped in both their spatial and temporal degrees of freedom for the optical micromanipulation of time-varying media.