Designing Multipolar Resonances in Dielectric Metamaterials.

Nikita A Butakov,Jon A Schuller

doi:10.1038/srep38487

Nikita A Butakov, Jon A Schuller

Open Access

https://doi.org/10.1038/srep38487

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Journal: Scientific Reports	Publication Date: Dec 1, 2016
Citations: 61	License type: CC BY 4.0

Affiliation: University of California, Santa Barbara

Abstract

Dielectric resonators form the building blocks of nano-scale optical antennas and metamaterials. Due to their multipolar resonant response and low intrinsic losses they offer design flexibility and high-efficiency performance. These resonators are typically described in terms of a spherical harmonic decomposition with Mie theory. In experimental realizations however, a departure from spherical symmetry and the use of high-index substrates leads to new features appearing in the multipolar response. To clarify this behavior, we present a systematic experimental and numerical characterization of Silicon disk resonators. We demonstrate that for disk resonators on low-index quartz substrates, the electric and magnetic dipole modes are easily identifiable across a wide range of aspect-ratios, but that higher order peaks cannot be unambiguously associated with any specific multipolar mode. On high-index Silicon substrates, even the fundamental dipole modes do not have a clear association. When arranged into arrays, resonances are shifted and pronounced preferential forward and backward scattering conditions appear, which are not as apparent in individual resonators and may be associated with interference between multipolar modes. These findings present new opportunities for engineering the multipolar scattering response of dielectric optical antennas and metamaterials, and provide a strategy for designing nano-optical components with unique functionalities.

Highlights

Dielectric resonators form the building blocks of nano-scale optical antennas and metamaterials
When the aspect-ratio of the disk becomes large, or when a high-index substrate is introduced, the breaking of spherical symmetry introduces new features into the multipolar modes
We demonstrate that changing the disk aspect-ratios or substrate refractive index can lead to overlapping electric and magnetic multipolar modes

Summary

C MD k4 6πε02 E 02 m 2

The electric fields are zero at the center and exhibit an approximately circular band of high intensity internal to the disk These field patterns are quite similar to the MD modes of spheres, and the multipolar decomposition is dominated by the MD moment. We speculate that this is due to the fulfillment of a preferentially backward scattering condition, or anti-Kerker condition, in which multipoles constructively interfere in the backward direction. We speculate that high-index substrates effectively reduce near-field coupling, due to reduced wavelengths, and that radiative interference leads to prominent red-shifting[52]

Conclusion

Methods