Broadband coherent wave control through photonic collisions at time interfaces

Coherent wave control exploits the interference among multiple waves impinging on a system to suppress or enhance outgoing signals based on their relative phase and amplitude. This process inherently requires the combination of energy exchanges among the waves and spatial interfaces to tailor their scattering. Here we explore the temporal analogue of this phenomenon, based on time interfaces that support instantaneous non-conservative scattering events for photons. Based on this mechanism, we demonstrate ultrabroadband temporal coherent wave control and the photonic analogue of mechanical collisions with phase-tunable elastic features. We apply them to erase, enhance and reshape arbitrary pulses by suitably tailoring the amplitude and phase of counterpropagating signals. Our findings provide a pathway to effectively sculpt broadband light with light without requiring spatial boundaries, within an ultrafast and low-energy platform. Coherent control is an interference technique widely used to control dynamic wave processes. Its analogue in the time domain allows the tailored suppression, enhancement and reshaping of optical pulses, and the mimicking of collisions between them.

Automated summary

Coherent wave control is used to suppress or enhance outgoing signals by exploiting the interference of multiple waves. In this study, we explore the temporal analogue of this phenomenon, showcasing ultrabroadband temporal coherent wave control using time interfaces. We demonstrate the photonic analogue of mechanical collisions with adjustable phase features, enabling the erasure, enhancement, and reshaping of optical pulses. This research provides a pathway for sculpting broadband light without spatial boundaries, within an ultrafast and low-energy platform.