Nanoscale sculpturing of single photons with dielectrics
Lead Research Organisation:
Imperial College London
Department Name: Physics
Abstract
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Organisations
People |
ORCID iD |
Stefan Maier (Principal Investigator) |
Publications
Mignuzzi S
(2018)
Energy-Momentum Cathodoluminescence Spectroscopy of Dielectric Nanostructures
in ACS Photonics
Remesh V
(2019)
Coherent Multiphoton Control of Gallium Phosphide Nanodisk Resonances
in ACS Photonics
Kepic P
(2021)
Optically Tunable Mie Resonance VO 2 Nanoantennas for Metasurfaces in the Visible
in ACS Photonics
Wang J
(2021)
All-Dielectric Crescent Metasurface Sensor Driven by Bound States in the Continuum
in Advanced Functional Materials
Córdova-Castro R
(2024)
Single-emitter super-resolved imaging of radiative decay rate enhancement in dielectric gap nanoantennas
in Light: Science & Applications
Poblet M
(2020)
Direct Detection of Optical Forces of Magnetic Nature in Dielectric Nanoantennas.
in Nano letters
Mignuzzi S
(2019)
Nanoscale Design of the Local Density of Optical States.
in Nano letters
Vidal C
(2024)
Fluorescence Enhancement in Topologically Optimized Gallium Phosphide All-Dielectric Nanoantennas
in Nano Letters
Kühne J
(2021)
Fabrication robustness in BIC metasurfaces
in Nanophotonics
Sortino L
(2019)
Enhanced light-matter interaction in an atomically thin semiconductor coupled with dielectric nano-antennas.
in Nature communications
Description | We have developed a method in order to strongly sculpt light fields on the sub-wavelength scale with dielectric nanoantennas. This could enable new forms of single-photon sources for quantum communications. Particular promise is the coupling of these antennas to low-dimensional materials. As a particular promising outcome, we have demonstrated that dielectrictic nanoantennas based on gallium phosphide show significant potential to enhance light emission from two-dimensional materials, published in two articles in Nature Communications and ACS Photonics. Dielectric nanoantennas compare favourably in this regard with their plasmonic, metallic counterparts. We regard this as a key finding going forward in terms of utilizing dielectric nanoantennas as a means to develop quantum light sources based on low-dimensional photon emitters. |
Exploitation Route | We have obtained internal funds at Imperial for impact acceleration and are currently exploring additional funding opportunities for follow-up work. |
Sectors | Digital/Communication/Information Technologies (including Software) |