Light-matter interactions in chip-integrated niobium nano-circuit arrays at optical fibre communication frequencies

TL;DR

This paper demonstrates how niobium nano-circuit arrays integrated on optical fibers can be used to tune light-matter interactions at communication wavelengths, enabling advanced photonic devices.

Contribution

It introduces a novel approach using niobium nano-gratings on fiber facets to control optical resonances and enhance light-matter interaction at telecom frequencies.

Findings

Optical resonance shifts with nano-grating periodicity.

Identification of Wood and Rayleigh anomalies in the response.

Potential for tunable metamaterials and plasmonic devices.

Abstract

The interplay between electronic properties and optical response enables the realization of novel types of materials with tunable responses. Superconductors are well known to exhibit profound changes in the electronic structure related to the formation of Cooper pairs, yet their influence on the electromagnetic response in the optical regime has remained largely unstudied. Photonics metamaterials offer new opportunities to enhance the light-matter interaction, boosting the influence of subtle effects on the optical response. The combination of photonic metamaterials and superconducting quantum circuits will have the potential to advance quantum computing and quantum communication technologies. Here, we introduce subwavelength photonic nano-grating circuit arrays on the facet of niobium thin films to enhance light-matter interaction at fiber optic communication frequencies. We find that optical resonance shifts to longer wavelengths with increasing nano-grating circuit periodicity, indicating a clear modulation of optical light with geometrical parameters of the device. Next to the prominent subwavelength resonance, we find a second feature consisting of adjacent dip and peak appears at slightly shorter wavelengths around the diffraction condition Py= lambda, corresponding to the Wood and Rayleigh anomalies of the first order grating diffraction. The observed tunable plasmonic photo-response in such compact and integrated nano-circuitry enables new types of metamaterial and plasmonics-based modulators, sensors, and bolometer devices.