HYPHONE

Hybrid Photonic Metamaterials at the Multiscale

Coordinatore	DANMARKS TEKNISKE UNIVERSITET    more  Organization address address: Anker Engelundsvej 1, Building 101A city: KONGENS LYNGBY postcode: 2800 contact info Titolo: Prof. Nome: Andrei Cognome: Lavrinenko Email: send email Telefono: +45 45256392 Fax: +45 45936581
Nazionalità Coordinatore	Denmark [DK]
Totale costo	228˙082 €
EC contributo	228˙082 €
Programma	FP7-PEOPLE Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013)
Code Call	FP7-PEOPLE-2011-IIF
Funding Scheme	MC-IIF
Anno di inizio	2012
Periodo (anno-mese-giorno)	2012-10-01   -   2014-12-04

 Partecipanti

#	participant	country	role	EC contrib. [€]
1	DANMARKS TEKNISKE UNIVERSITET  Organization address address: Anker Engelundsvej 1, Building 101A city: KONGENS LYNGBY postcode: 2800 contact info Titolo: Prof. Nome: Andrei Cognome: Lavrinenko Email: send email Telefono: +45 45256392 Fax: +45 45936581	DK (KONGENS LYNGBY)	coordinator	228˙082.20

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 Obiettivo del progetto (Objective)

'In recent modern optics, two rapidly developing branches can be identified: (i) photonics, which studies materials structured on a mesoscopic (micrometer or wavelength) scale, and (ii) optics of metamaterials, which are structured on a nanometer (deeply subwavelength) scales. In both these branches, revolutionary degree of control over light propagation and light-matter interaction has been achieved. However, they still remain relatively isolated fields of study. This project is aimed at developing a unified theoretical paradigm of hybrid multiscale photonics by combining the knowledge of photonics, plasmonics, and optics of metamaterials. It is expected that synergies between photonic band gap phenomena and exotic plasmonic excitations present in metamaterials will significantly enhance the possibilities for controlling the flow of light and tailoring light-matter interaction at the nanoscale. Central to the project are hybrid photonic/metamaterial systems where the elements (e.g., layers) are arranged in a periodic or aperiodic “superstructure” and themselves contain metamaterials “substructured” on a deeply subwavelength scale. The studies will start with simple geometries such as metal-dielectric multilayers with micrometer-scale superstructure and nanometer-scale substructures, moving on to more complicated 2D/3D systems based on nanowires and nanoparticle clusters. The resulting theoretical concept, applied to hybrid photonic/plasmonic/active systems (such as metal nanoparticle arrays embedded in polymer matrices doped with dye molecules), will be used to design novel plasmonic materials with low loss and/or optical gain. It will also lead to novel physical concepts such as random spasers or deterministically aperiodic photonic/plasmonic nanolasers, with applications in efficient on-chip frequency/polarization filtering, on-chip label-free sensing, and on-chip device-enhanced light-matter interactions.'