Engineering polariton non-linearity in organic and hybrid-semiconductor microcavities
Lead Research Organisation:
University of Southampton
Department Name: Sch of Physics and Astronomy
Abstract
Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.
Publications
Christogiannis N
(2013)
Characterizing the Electroluminescence Emission from a Strongly Coupled Organic Semiconductor Microcavity LED
in Advanced Optical Materials
Kammann E
(2012)
Crossover from photon to exciton-polariton lasing
in New Journal of Physics
Rindermann JJ
(2011)
Dependence of resonance energy transfer on exciton dimensionality.
in Physical review letters
Rindermann JJ
(2011)
Gauging the flexibility of fluorescent markers for the interpretation of fluorescence resonance energy transfer.
in Journal of the American Chemical Society
Liao Y
(2014)
Highly Efficient Flexible Hybrid Nanocrystal-Cu(In,Ga)Se 2 (CIGS) Solar Cells
in Advanced Energy Materials
Coles D
(2013)
Imaging the polariton relaxation bottleneck in strongly coupled organic semiconductor microcavities
in Physical Review B
Rindermann J
(2012)
In-situ electrical characterisation of a photodiode during nano-structuring with a focussed ion beam
in Applied Physics A
Cilibrizzi P
(2014)
Linear wave dynamics explains observations attributed to dark solitons in a polariton quantum fluid.
in Physical review letters
Kammann E
(2012)
Nonlinear optical spin Hall effect and long-range spin transport in polariton lasers.
in Physical review letters
Poltavtsev S
(2014)
Optics of spin-noise-induced gyrotropy of an asymmetric microcavity
in Physical Review B
Description | Our research has underpinned some of the recent advances in the first observations of organic polariton condensation and polariton-mediated energy transfer achieved between different organic materials. |
Exploitation Route | We believe that our research will make polaritonics the basis for future optoelectronic technologies, including thresholdless lasers, THz emitters (with applications in non-invasive medical imaging and explosives detection), and a range of new quantum information technologies. Indeed, by modifying the basic electronic functionality of materials, hybrid polaritonics could have even wider impact in the areas from chemical sensing to catalysis and photo-biology. |
Sectors | Education,Energy |
URL | http://www.hybrid.soton.ac.uk/ |
Description | University of Southampton |
Amount | £130,000 (GBP) |
Funding ID | EU FP7 Network of Excellence |
Organisation | University of Southampton |
Sector | Academic/University |
Country | United Kingdom |
Start | 09/2009 |
End | 08/2013 |