Abstract

Abstract High-index dielectric nanostructures have emerged as an appealing complement to plasmonic nanostructures, offering similar light management capabilities at the nanoscale but free from the inherent optical losses. Despite the great interest in these all-dielectric architectures, their fabrication still requires cumbersome fabrication techniques that limit their implementation in many applications. Hence, the great interest in alternative scalable procedures. Among those, the fabrication of silicon spheres is at the forefront, with several routes available in the literature. However, the exploitation of the Mie modes sustained by these silicon resonators is limited over large areas by polydispersity or a lack of long-range order. Here, we present an all-dielectric metamaterial fabricated with a low cost and highly scalable technique: a combination of soft imprinting nanolithography and chemical vapor deposition. The resulting all-dielectric metasurface is composed of an array of silicon hemispheres on top of a high refractive index dielectric substrate. This architecture allows the exploitation of high-quality Mie resonances at a large scale due to the high monodispersity of the hemispheres organized in a single crystal two-dimensional lattice. The optical response of the metasurface can be engineered by the design parameters of the nanoimprinted structure. We further demonstrate the potential of this platform to enhance light emission by coupling dye molecules to the sustained Mie resonances and measuring both an eight-fold amplified signal and a triple lifetime reduction.

Highlights

  • Metallic nanostructures have been intensively studied in recent years due to their capacity to generate a strong light concentration at the sub-wavelength scale, providing new opportunities in photodetection, photocatalysis, photovoltaics, surface-enhanced Raman scattering, photothermal therapy and optical tweezers [1,2,3,4,5,6,7,8,9,10]

  • We demonstrate a large area silicon hemisphere array that serves as a platform to excite electric and magnetic resonances tunable in the wavelength range from 700 nm to 2000 nm

  • The silicon hemispheres organized in a two-dimensional lattice act as Mie resonators and diffraction scatterers, while the residual layer behaves as a high refractive index waveguide capable of supporting quasi-guided modes (QGM) (Supporting Figures S2 and S3)

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Summary

Introduction

Metallic nanostructures have been intensively studied in recent years due to their capacity to generate a strong light concentration at the sub-wavelength scale, providing new opportunities in photodetection, photocatalysis, photovoltaics, surface-enhanced Raman scattering, photothermal therapy and optical tweezers [1,2,3,4,5,6,7,8,9,10]. High-index dielectric nanostructures exhibit resonances with both an ­electric and a magnetic nature, which can further be exploited in novel photonic phenomena such as magnetic perfect reflection, directional light propagation, electric and magnetic field enhancement, wavefront shaping and Huygens’s ­metasurfaces [22,23,24,25,26,27,28,29,30]. We demonstrate a large area silicon hemisphere array that serves as a platform to excite electric and magnetic resonances tunable in the wavelength range from 700 nm to 2000 nm. The final metasurface is composed of a two-dimensional array of highly monodisperse silicon hemispheres on a silicon-infiltrated TiO2 (Si/ TiO2) waveguide This inventive architecture is designed to simultaneously sustain Mie resonances from the hemispheres and the quasi-guided modes (QGM) diffracted by the periodic lattice with high Q-factors [40]. The intense optical response of the metasurface is used to achieve a strong enhancement of the photoluminescence (PL) of NIR light-emitting dye molecules coupled to the resonant modes

Unconventional nanofabrication of the metasurface
Si CVD growth
Enhancing PL with all-dielectric metasurfaces
Conclusions
TiO2 backbone fabrication
Silicon infiltration
Dye deposition
FDTD modeling
F ar-field reflection measurements
Findings
PL measurements

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