Harnessing the frequency eigenchannels of ultrafast time-varying media

TL;DR

This paper demonstrates waveform shaping in ultrafast time-varying media by experimentally controlling incident pulses to optimize spectral transformations, enabling new functionalities in wave manipulation across various domains.

Contribution

It introduces a method to identify and shape incident waveforms for desired spectral interactions in ultrafast time-varying media, advancing control over wave-medium interactions.

Findings

Identified eigenpulses that reflect without spectral distortion.

Achieved broadband absorption through temporal modulation.

Concentrated energy into specific frequency bands upon reflection.

Abstract

Control over the interaction of waves with ultrafast time-varying materials - those that change on a time-scale commensurate with the wave period - holds much promise for developing a raft of new technologies. Time-varying materials exchange energy with the waves passing through them, thus exhibiting entirely new phenomena not possible with static media. Work to date has largely considered the realisation of ultrafast time-varying materials, with much less attention paid to how their interaction depends upon the shape of the incident waves themselves. Here we experimentally demonstrate 'waveform shaping' within ultrafast time-varying media: temporal shaping of incident pulses to optimise specific dynamic material interactions. We create an ultrafast time-varying medium by rapidly modulating a waveguide termination, and measure the spectrally resolved reflection matrix. Analysis of this reflection matrix enables the identification of the incident waveforms that undergo a desired spectral transformation. Using this approach, we first characterise the medium's eigenpulses; temporal modes that reflect from the medium without spectral distortion. Next, we identify the waveforms that are either maximally or minimally reflected, enabling strong broadband absorption arising from the temporal modulation of the medium. Finally, we show how energy can be optimally concentrated into a user-defined set of frequency bands upon reflection. Our work paves the way towards new applications of ultrafast time-varying media, spanning from optics to microwaves and acoustics.