Continuous spectral and coupling-strength encoding with dual-gradient metasurfaces

TL;DR

This paper introduces a dual-gradient metasurface that can continuously encode spectral and coupling-strength parameters of light-matter interactions, enabling advanced control and sensing capabilities in nanophotonics.

Contribution

The authors develop a novel 2D array of nanoresonators supporting 27,500 modes, allowing simultaneous and continuous encoding of spectral and quality factor parameters.

Findings

Demonstrated enhanced molecular sensing using the metasurface

Unveiled an additional coupling-based spectroscopic data dimension

Achieved near-theoretical maximum mode density in metasurface design

Abstract

Enhancing and controlling light-matter interactions is crucial in nanotechnology and material science, propelling research on green energy, laser technology, and quantum cryptography. Central to enhanced light-matter coupling are two parameters: the spectral overlap between an optical cavity mode and the material's spectral features (e.g., excitonic or molecular absorption lines), and the quality factor of the cavity. Controlling both parameters simultaneously is vital, especially in complex systems requiring extensive data to uncover the numerous effects at play. However, so far, photonic approaches have focused solely on sampling a limited set of data points within this 2D parameter space. Here we introduce a nanophotonic approach that can simultaneously and continuously encode the spectral and quality factor parameter space of light-matter interactions within a compact spatial area. Our novel dual-gradient metasurface design is composed of a 2D array of smoothly varying subwavelength nanoresonators, each supporting a unique mode. This results in 27,500 distinct modes within one array and a resonance density approaching the theoretical upper limit for metasurfaces. By applying our dual-gradient to surface-enhanced molecular sensing, we demonstrate the importance of coupling tailoring and unveil an additional coupling-based dimension of spectroscopic data. Our metasurface design paves the way for generalized light-matter coupling metasurfaces, leading to advancements in the field of photocatalysis, chemical sensing, and entangled photon generation.