# Integrating quantum-dots and dielectric Mie resonators: a hierarchical   metamaterial inheriting the best of both

**Authors:** Antonio Capretti, Arnon Lesage, Tom Gregorkiewicz

arXiv: 1703.10074 · 2017-08-23

## TL;DR

This paper demonstrates a hierarchical metamaterial combining silicon nanocrystals and dielectric Mie resonators, achieving enhanced photoluminescence and spectrally-selective absorption without lossy components, with potential applications in solar energy and photonic devices.

## Contribution

The work introduces a novel hierarchical design embedding Si-NCs into SiO2 nanocylinders, preserving luminescent properties while enabling tunable absorption, surpassing previous approaches that relied on plasmonic components.

## Key findings

- Achieved +30% PL intensity with fewer Si-NCs compared to planar films.
- Demonstrated spectrally-selective absorption peaks up to 50%.
- Enhanced absorption and PL without affecting lifetime or extraction efficiency.

## Abstract

Nanoscale dielectric resonators and quantum-confined semiconductors have enabled unprecedented control over light absorption and excited charges, respectively. In this work, we embed luminescent silicon nanocrystals (Si-NCs) into a 2D array of SiO2 nanocylinders, and experimentally prove a powerful concept: the resulting metamaterial preserves the radiative properties of the Si-NCs and inherits the spectrally-selective absorption properties of the nanocylinders. This hierarchical approach provides increased photoluminescence (PL) intensity obtained without utilizing any lossy plasmonic components. We perform rigorous calculations and predict that a freestanding metamaterial enables tunable absorption peaks up to 50% in the visible spectrum, in correspondence of the nanocylinder Mie resonances and of the grating condition in the array. We experimentally detect extinction spectral peaks in the metamaterial, which drive enhanced absorption in the Si-NCs. Consequently, the metamaterial features increased PL intensity, obtained without affecting the PL lifetime, angular pattern and extraction efficiency. Remarkably, our best-performing metamaterial shows +30% PL intensity achieved with a lower amount of Si-NCs, compared to an equivalent planar film without nanocylinders, resulting in a 3-fold average PL enhancement per Si-NC. The principle demonstrated here is general and the Si-NCs can be replaced with other semiconductor quantum dots, rare-earth ions or organic molecules. Similarly, the dielectric medium can be adjusted on purpose. This spectral selectivity of absorption paves the way for an effective light down-conversion scheme to increase the efficiency of solar cells. We envision the use of this hierarchical design for other efficient photovoltaic, photo-catalytic and artificial photosynthetic devices with spectrally-selective absorption and enhanced efficiency.

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Source: https://tomesphere.com/paper/1703.10074