# Strong radiative interactions and subradiance in disordered   metamaterials

**Authors:** Stewart D. Jenkins, Nikitas Papasimakis, Salvatore Savo, Nikolay I., Zheludev, Janne Ruostekoski

arXiv: 1812.10452 · 2018-12-27

## TL;DR

This study combines experiments and simulations to explore how disorder affects strong radiative interactions and subradiance in large, disordered metamaterial arrays, revealing the microscopic origins and the impact on electromagnetic response.

## Contribution

It provides a detailed microscopic description linking disorder, cooperative interactions, and electromagnetic response in disordered metamaterials, supported by experimental and simulation comparisons.

## Key findings

- Disorder causes spatial localization of eigenmodes in metamaterials.
- Strong field-mediated interactions lead to cooperative electromagnetic responses.
- Disorder shifts the transmission resonance and induces a cooperative Lamb shift.

## Abstract

We provide detailed comparisons between experimental findings and numerical simulations of large cooperatively interacting, spatially disordered metamaterial arrays, consisting of asymmetrically split rings. Simulation methods fully incorporate strong field-mediated inter-meta-atom interactions between discrete resonators and statistical properties of disorder, while approximating the resonators' internal structure. Despite the large system size, we find a qualitative agreement between the simulations and experiments, and characterize the microscopic origins of the observed disorder response. Our microscopic description of macroscopic electrodynamics reveals how the response of disordered arrays with strong field-mediated interactions is inherently linked to their cooperative response to electromagnetic waves where the multiple scattering induces strong correlations between the excitations of individual resonators. Whereas for a regular array the response can be overwhelmingly dominated by a spatially-extended collective eigenmode with subradiant characteristics, a gradual increase of the positional disorder rapidly leads to a spatial localization of both the electric and magnetic dipolar excitation profile of this eigenmode. We show how the effects of disorder and cooperative interactions are mapped onto the transmission resonance in the far field spectrum and measure the "cooperative Lamb shift" of the resonance that is shifting toward the red as the disorder increases. The interplay between the disorder and interactions generally is most dramatic in the microwave arrays, but we find that in suitable regimes the strong disorder effects can be achieved also for plasmonic optical systems.

## Full text

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## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/1812.10452/full.md

## References

77 references — full list in the complete paper: https://tomesphere.com/paper/1812.10452/full.md

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Source: https://tomesphere.com/paper/1812.10452