Active Plasmonics: Electronic and All-optical Control of Photonic Signals on Sub-wavelength Scales
Lead Research Organisation:
Queen's University of Belfast
Department Name: Sch of Mathematics and Physics
Abstract
The term 'plasmonics' refers to the science and technology dealing with manipulation of electromagnetic signals by coherent coupling of photons to free electron oscillations at the interface between a conductor and a dielectric. This field of research has emerged as an extremely promising technology with several main fields of application: information technologies, energy, high-density data storage, life sciences and security. The opportunity to guide light in the form of surface plasmon waves on metallic films is attractive for the development of integrated photonic chips where the information can be processed all-optically without the need of electronic-to-optical and optical-to-electronic conversion, as well as for integrating photonics with silicon electronics on a fully compatible platform. Performance of optoelectronic devices, such as light emitting diodes and photodetectors, can also be improved by integrating them with plasmonic nanostructures. Recent research in plasmonics has led to significant progress in development of various passive plasmonic components, such as waveguides, plasmonic crystals, plasmonic metamaterials, with tailored photonic properties. Plasmonic studies have, however, almost exclusively concentrated on pure metallic nanostructures and passive devices with properties fixed by the nanostructure parameters. At the same time, real-life applications require active control to achieve signal switching and modulation, amplification to compensate losses along with the direct generation and detection of plasmons. All these can be realised if plasmonic nanostructures are hybridised with functional (molecular or ferroelectric) materials. Here we propose to develop and study hybrid plasmonic nanostructures consisting of nanostructured metals combined with dielectrics to enable active functionalities in plasmonic circuitry. This project will unlock the plasmonics' potential for improvement of real-world photonic and optoelectronic devices and provide insight into physical phenomena which are important for various areas of optical physics and photonic technologies.
Organisations
- Queen's University of Belfast (Lead Research Organisation)
- Australian Research Council (Collaboration)
- University College Cork (Collaboration)
- Argonne National Laboratory (Collaboration)
- Intel Corporation (Collaboration)
- National Physical Laboratory NPL (Project Partner)
- Intel Ireland Ltd (Project Partner)
Publications
Perevedentsev A
(2015)
Solution-crystallization and related phenomena in 9,9-dialkyl-fluorene polymers. II. Influence of side-chain structure.
in Journal of polymer science. Part B, Polymer physics
Perevedentsev A
(2014)
Interplay between solid state microstructure and photophysics for poly(9,9-dioctylfluorene) within oriented polyethylene hosts
in Journal of Polymer Science Part B: Polymer Physics
Perevedentsev A
(2016)
Spectroscopic properties of poly(9,9-dioctylfluorene) thin films possessing varied fractions of ß-phase chain segments: enhanced photoluminescence efficiency via conformation structuring.
in Journal of polymer science. Part B, Polymer physics
Perevedentsev A
(2015)
Dip-pen patterning of poly(9,9-dioctylfluorene) chain-conformation-based nano-photonic elements.
in Nature communications
Perevedentsev A
(2015)
Solution-Crystallization and Related Phenomena in 9,9-Dialkyl-Fluorene Polymers. I. Crystalline Polymer-Solvent Compound Formation for Poly(9,9-dioctylfluorene).
in Journal of polymer science. Part B, Polymer physics
Perevedentsev, Aleksandr
(2015)
Interplay Between Solid State Microstructure and Photophysics for Poly(9,9-dioctylfluorene) within Oriented Polyethylene Hosts
Perevedentsev, Aleksandr
(2015)
Solution-crystallization and related phenomena in 9,9-dialkyl-fluorene polymers. II. Influence of side-chain structure
Poddubny A
(2012)
Microscopic model of Purcell enhancement in hyperbolic metamaterials
in Physical Review B
Poddubny A
(2012)
Tailoring and enhancing spontaneous two-photon emission using resonant plasmonic nanostructures
in Physical Review A
Related Projects
| Project Reference | Relationship | Related To | Start | End | Award Value |
|---|---|---|---|---|---|
| EP/H000917/1 | 31/08/2009 | 30/09/2010 | £5,176,637 | ||
| EP/H000917/2 | Transfer | EP/H000917/1 | 30/09/2010 | 30/08/2015 | £4,462,875 |
| Title | In Nanophotonics Lab: Hyperspectral SNOM (a short film by Fanny Hoetzeneder) |
| Description | A short movie filmed in our lab. |
| Type Of Art | Film/Video/Animation |
| Year Produced | 2012 |
| Impact | General Public engagement |
| URL | http://vimeo.com/59812566 |
| Title | Nano Nail (by Imogen Clarke) |
| Description | Nano Nail is an artistic installation with nanoscale features in human body. |
| Type Of Art | Artefact (including digital) |
| Year Produced | 2014 |
| Impact | Public Engagement, student recruitment, tells general public about nano |
| URL | http://imogen-clarke.4ormat.com/nano-nail#0 |
| Title | Nano Sublimation (by Nedyalka Panova) |
| Description | NANO Sublimation is an installation depicting in conceptual way plasmonic metamaterial. |
| Type Of Art | Artwork |
| Year Produced | 2013 |
| Impact | Was exhibited in art galleries in London. Currently permanently exhibited at Physics Department at King's College. General public engagement, student recruitment. |
| URL | http://www.nedyalkapanova.com/ |
| Description | The term 'plasmonics' refers to the science and technology dealing with manipulation of electromagnetic signals by coherent coupling of photons to free electron oscillations at the interface between a conductor and a dielectric. This field of research has emerged as an extremely promising technology with several main fields of application: information technologies, energy, high-density data storage, life sciences and security. The opportunity to guide light in the form of surface plasmon waves on metallic films is attractive for the development of integrated photonic chips where the information can be processed all-optically without the need of electronic-to-optical and optical-to-electronic conversion, as well as for integrating photonics with silicon electronics on a fully compatible platform. Performance of optoelectronic devices, such as light emitting diodes and photodetectors, can also be improved by integrating them with plasmonic nanostructures. Recent research in plasmonics has led to significant progress in development of various passive plasmonic components, such as waveguides, plasmonic crystals, plasmonic metamaterials, with tailored photonic properties. We have developed plasmonic applications beyond traditional passive devices to achieve plasmonic circuitry components with active functionalities: sources, detectors, modulators and switches, allowing efficient generation and manipulation of optical signals at the nanoscale. Plasmonic nanolasers, including ultrafast nanolasers were developed. Ultrafast (sup 1 ps) switches based on plasmonic materials demonstrated integratable with plasmonic, Si-photonics and other types of phtonic circuitries. Active control to achieve signal switching and modulation, amplification to compensate losses along with the direct generation and detection of plasmons were achieved. All these were realised in plasmonic nanostructures hybridised with functional (molecular or ferroelectric) materials. |
| Exploitation Route | We are exploring ways to licence our patents and created a start-up company. |
| Sectors | Digital/Communication/Information Technologies (including Software) Electronics Other |
| URL | http://www.activeplasmonics.org |
| Description | 4 patents have been applied for. Start-up company "Causeway Photonics" created. Nanophotonics Foresight report was instrumental for defining H2020 Photonics workprogramme. Outreach to general public through collaborations with artists. |
| Sector | Digital/Communication/Information Technologies (including Software),Other |
| Impact Types | Cultural Economic Policy & public services |
| Description | Contribution to Europen Nanophotonics Foresight Report |
| Geographic Reach | Asia |
| Policy Influence Type | Citation in other policy documents |
| URL | http://www.nanophotonicseurope.org/ |
| Description | Nanophotonics: A Forward Look |
| Geographic Reach | Asia |
| Policy Influence Type | Citation in other policy documents |
| URL | http://www.nanophotonicseurope.org/ |
| Description | FET CCA |
| Amount | € 640,000 (EUR) |
| Organisation | European Commission |
| Department | Horizon 2020 |
| Sector | Public |
| Country | European Union (EU) |
| Start | 01/2017 |
| End | 12/2018 |
| Description | Argonne |
| Organisation | Argonne National Laboratory |
| Country | United States |
| Sector | Public |
| PI Contribution | Investigation on nonlinear and ultrafast response of plasmonic nanostructures |
| Collaborator Contribution | User access to the ultrafast spectroscopy facilities |
| Impact | Publications, conference papers, exchange visits, internal ANL collaborative grants |
| Start Year | 2010 |
| Description | CUDOS |
| Organisation | Australian Research Council |
| Department | Centre for Ultrahigh bandwidth Devices for Optical Systems (CUDOS) |
| Country | Australia |
| Sector | Public |
| PI Contribution | Collaboration on theory of plasmonic devices |
| Collaborator Contribution | Collaboration on theory of plasmonic devices |
| Impact | Publications, conference papers, joint grant applications |
| Start Year | 2011 |
| Description | INTEL |
| Organisation | Intel Corporation |
| Country | United States |
| Sector | Private |
| PI Contribution | Reserach in plasmonic on-chip interconnects |
| Collaborator Contribution | part-funding of a PhD student, Advisory Board |
| Impact | Publications, conference papers |
| Start Year | 2009 |
| Description | Tyndall |
| Organisation | University College Cork |
| Department | Tyndall National Institute |
| Country | Ireland |
| Sector | Academic/University |
| PI Contribution | Design and characterisation of plasmonic-enhanced VCSEL lasers for high-density data storage applications |
| Collaborator Contribution | Fabrication of plasmonic-enhanced VCSEL lasers for high-density data storage applications |
| Impact | Publications, conference papers |
| Start Year | 2010 |
| Company Name | Causeway Sensors |
| Description | Causeway Sensors develops nanotechnology designed to provide kinetic analysis during biotherapeutic production to improve candidate selection for drug discovery. |
| Year Established | 2013 |
| Impact | Customers include biology laboratories in academia, Institute laboratories and diverse industry. |
| Website | http://www.causewaysensors.com |
| Description | London Science Festival 2011 |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | Yes |
| Geographic Reach | Local |
| Primary Audience | Public/other audiences |
| Results and Impact | Our image "Plasmonic ring-resonator" was a joint (with the other image) best-seller. Public could buy prints of the exhibited image with proceed for charity. Generated lots of interest in general public in science and photonics in particular. |
| Year(s) Of Engagement Activity | 2011 |
| URL | http://londonsciencefestival.com/ |