Summary
The aim of this innovative and high-impact interdisciplinary proposal is to investigate the potential properties and applications
of plasmonic metallic nanostructures that enable the confinement of light to scales beyond the diffraction limit, known as
quantum plasmonics. Latest studies have revealed the quantization of surface plasmon polaritons (SPPs). It could be the
stepping stone for the generation of miniaturized photonic components for the quantum control of light. This implies that the
SPPs would represent a totally new sort of information carrier for nanoscale circuitry, enabling a revolutionary bridge
between current diffraction-limited microphotonics and bandwith-limited nanoelectronics, paving the way for integrated
quantum information processing. Thus, in a first stage we will develop integrated nanoscale quantum plasmonics building
blocks on-a-chip, such as efficient single-photon sources or transistors, which is the component required for the fabrication
of true nanoscale quantum computing logic gates. We also plan to exploit the low-Ohmic-losses and prospects for large
scale production of ultra-compact cutting-edge graphene plasmonic circuits. This research will be lastly applied to single
molecule sensing. Experiments will be performed using innovative techniques for nanofabrication of photonic nanostructures
and for characterization. The expected results will allow taking advantage of quantum interference effects, setting up the
optical response of the extremely low losses Long Range (LR) SPPs modes within a quantum framework and showing that
graphene layers produce strong light-matter interaction and extreme optical field confinement. The results will be compared
with ab initio simulations, giving a precise and consistent experimental and theoretical panorama of quantum plasmonics.
of plasmonic metallic nanostructures that enable the confinement of light to scales beyond the diffraction limit, known as
quantum plasmonics. Latest studies have revealed the quantization of surface plasmon polaritons (SPPs). It could be the
stepping stone for the generation of miniaturized photonic components for the quantum control of light. This implies that the
SPPs would represent a totally new sort of information carrier for nanoscale circuitry, enabling a revolutionary bridge
between current diffraction-limited microphotonics and bandwith-limited nanoelectronics, paving the way for integrated
quantum information processing. Thus, in a first stage we will develop integrated nanoscale quantum plasmonics building
blocks on-a-chip, such as efficient single-photon sources or transistors, which is the component required for the fabrication
of true nanoscale quantum computing logic gates. We also plan to exploit the low-Ohmic-losses and prospects for large
scale production of ultra-compact cutting-edge graphene plasmonic circuits. This research will be lastly applied to single
molecule sensing. Experiments will be performed using innovative techniques for nanofabrication of photonic nanostructures
and for characterization. The expected results will allow taking advantage of quantum interference effects, setting up the
optical response of the extremely low losses Long Range (LR) SPPs modes within a quantum framework and showing that
graphene layers produce strong light-matter interaction and extreme optical field confinement. The results will be compared
with ab initio simulations, giving a precise and consistent experimental and theoretical panorama of quantum plasmonics.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/704998 |
| Start date: | 01-03-2016 |
| End date: | 29-12-2018 |
| Total budget - Public funding: | 170 121,60 Euro - 170 121,00 Euro |
Cordis data
Original description
The aim of this innovative and high-impact interdisciplinary proposal is to investigate the potential properties and applicationsof plasmonic metallic nanostructures that enable the confinement of light to scales beyond the diffraction limit, known as
quantum plasmonics. Latest studies have revealed the quantization of surface plasmon polaritons (SPPs). It could be the
stepping stone for the generation of miniaturized photonic components for the quantum control of light. This implies that the
SPPs would represent a totally new sort of information carrier for nanoscale circuitry, enabling a revolutionary bridge
between current diffraction-limited microphotonics and bandwith-limited nanoelectronics, paving the way for integrated
quantum information processing. Thus, in a first stage we will develop integrated nanoscale quantum plasmonics building
blocks on-a-chip, such as efficient single-photon sources or transistors, which is the component required for the fabrication
of true nanoscale quantum computing logic gates. We also plan to exploit the low-Ohmic-losses and prospects for large
scale production of ultra-compact cutting-edge graphene plasmonic circuits. This research will be lastly applied to single
molecule sensing. Experiments will be performed using innovative techniques for nanofabrication of photonic nanostructures
and for characterization. The expected results will allow taking advantage of quantum interference effects, setting up the
optical response of the extremely low losses Long Range (LR) SPPs modes within a quantum framework and showing that
graphene layers produce strong light-matter interaction and extreme optical field confinement. The results will be compared
with ab initio simulations, giving a precise and consistent experimental and theoretical panorama of quantum plasmonics.
Status
CLOSEDCall topic
MSCA-IF-2015-EFUpdate Date
28-04-2024
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