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Metabeyond SIGNED

Beyond metamaterials: Designing novel optical materials from Angstrom-scale interactions

Total Cost €

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EC-Contrib. €

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Partnership

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 Metabeyond project word cloud

Explore the words cloud of the Metabeyond project. It provides you a very rough idea of what is the project "Metabeyond" about.

arises    electrons    good    tailoring    mass    either    materials    interactions    conventional    modules    quality    fabrication    limitations    forces    precision    single    electronic    sheet    plasmons    nanometers    atomic    metastructures    metallic    photonic    nanoscale    transport    discovered    wavelengths    atom    technological    periodicity    emission    nanophotonics    canvas    optoelectronic    noble    multiple    arrangements    contrary    dichalcogenides    transition    angstrom    larger    interacting    combining    2d    date    notion    dielectric    newly    regime    directional    lattice    der    heterostructures    complexity    waals    semiconducting    geometrical    thickness    stacks    structural    fundamental    exploring    intercalation    material    realization    exfoliation    engineered    casimir    drastically    anisotropic    constant    spanning    density    subject    bulky    routes    components    ones    explored    respectively    vdw    dimensional    separated    miniaturization    utilizing    photonics    microns    scalable    photons    modern    meta    electron    excitons    tens    reflective    light    van    metals    metamaterials    advantage    practical    experimental    hundreds    metal    functional    contrast    graphene    science    surpassing    yield    vibrations   

Project "Metabeyond" data sheet

The following table provides information about the project.

Coordinator
KING'S COLLEGE LONDON 

Organization address
address: STRAND
city: LONDON
postcode: WC2R 2LS
website: www.kcl.ac.uk

contact info
title: n.a.
name: n.a.
surname: n.a.
function: n.a.
email: n.a.
telephone: n.a.
fax: n.a.

 Coordinator Country United Kingdom [UK]
 Total cost 183˙454 €
 EC max contribution 183˙454 € (100%)
 Programme 1. H2020-EU.1.3.2. (Nurturing excellence by means of cross-border and cross-sector mobility)
 Code Call H2020-MSCA-IF-2017
 Funding Scheme MSCA-IF-EF-ST
 Starting year 2019
 Duration (year-month-day) from 2019-09-01   to  2021-08-31

 Partnership

Take a look of project's partnership.

# participants  country  role  EC contrib. [€] 
1    KING'S COLLEGE LONDON UK (LONDON) coordinator 183˙454.00

Map

 Project objective

Modern state-of-the-art optoelectronic devices are subject to constant miniaturization. While electronic modules are still scalable, photonic components remain bulky, due to drastically larger wavelengths of photons compared to electrons. Light-matter interactions in the nanoscale can be engineered with metamaterials, by controlling the structural complexity of materials systems. However, practical fabrication limitations do not allow good precision beyond tens of nanometers, neither do they yield high-quality material properties. By contrast, two-dimensional (2D) materials like graphene or transition-metal dichalcogenides open routes for controlling light-matter interactions down to single atom thickness. To date, graphene-photonics investigate either a single sheet, or multiple ones separated by hundreds of nanometers-microns. I propose exploring a new regime of atomic-scale photonics, studying interacting 2D materials in van der Waals (vdW) heterostructures with periodicity in the Angstrom-scale. The transport properties of vdW stacks are already being explored, and their experimental realization is within reach with growth, exfoliation and intercalation. Contrary to conventional nanophotonics where light-matter interactions are tailored by controlling the geometrical features of metamaterials, at the atomic-scale arises the notion of (meta)materials by material design. Combining lattice vibrations, excitons and plasmons, supported in the large canvas of newly discovered 2D materials spanning dielectric, semiconducting and metallic properties, respectively, can lead to functional Angstrom-scale metastructures. Addressing both technological needs and fundamental science issues, my objectives include: taking advantage of graphene’s low-electron mass for surpassing the reflective properties of noble metals, utilizing the low mass density of vdW systems for tailoring Casimir forces, and exploring anisotropic vdW arrangements for directional light emission.

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The information about "METABEYOND" are provided by the European Opendata Portal: CORDIS opendata.

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