Plasmonic metamaterial time crystal
Abstract
Periodically driven optical materials and metamaterials have recently emerged as a promising platform for realizing photonic time crystals (PTCs), which are systems whose optical properties are strongly and periodically modulated on timescales comparable to the optical cycle of light. These time-varying structures are the temporal counterparts of spatial photonic crystals (SPCs), for which a large and periodic dielectric contrast is achieved spatially on wavelength scales. Just as SPCs have revolutionized control over light-matter interactions by engineering the photonic density of states in space, PTCs promise comparable breakthroughs from a fundamentally new perspective: a temporal one. However, harnessing such phenomena all-optically poses severe experimental challenges, as it requires order-unity modulation depths of a material's optical properties on ultrafast timescales comparable to the light cycle, a regime that has remained elusive to date. Here, we demonstrate the first all-optical realization of a photonic time crystal, achieved with a surface plasmon cavity metamaterial operating at Terahertz (THz) frequencies. We demonstrate strong (near-unity) and coherent (sub-optical cycle) periodic driving of the plasmonic metamaterial enabled by field-induced dynamical modulation of the carriers' kinetic energy and effective mass - reaching up to 80% of their rest mass. Our spectroscopic measurements reveal a transition into the PTC regime mediated by an exceptional point, at which two Floquet-driven optical eigenmodes coalesce. In the PTC regime, emergent gain is shown to reduce plasmonic losses by more than 50% and we predict plasmonic lasing to be within experimental reach. These results pave the way for temporal engineering of losses and light-matter interactions in plasmonic systems, and establish a robust new platform for time-domain photonics.
Cite
@article{arxiv.2510.02845,
title = {Plasmonic metamaterial time crystal},
author = {Tingwen Guo and Jules Sueiro and Gian Marcello Andolina and Artem Levchuk and Stefano Ponzoni and Romain Grasset and Donald Monthe and Ian Aupiais and Dmitri Daineka and Javier Briatico and Thales VAG de Oliveira and Alexey Ponomaryov and Atiqa Arshad and Arjun Karimbana-Kandy and Gulloo Lal Prajapati and Igor Ilyakov and Jan-Christoph Deinert and Sebastian F. Maehrlein and Luca Perfetti and Marco Schiro and Yannis Laplace},
journal= {arXiv preprint arXiv:2510.02845},
year = {2026}
}
Comments
10 pages, 4 figures