Functional organic molecules and metal and semiconductor nanocrystals represent attractive building blocks due to their composition-, size- and structure-dependent electronic properties, and the ability to design and manipulate these properties via low-cost and established chemical synthesis. Building from the pressing need of the European market to develop novel, scalable and cheaper technologies for sensing applications, and the main objective of the HYSENS project is to exploit inexpensive organic functional molecules and inorganic nanocrystals as building blocks to synthesize novel high-knowledge materials for the development of sensors for Group I, II transition metal cations and anions (Cl-, NO3-).
The hybrid material intelligence resulting from the engineered combination of individual units will allow the execution of logic functions able to reduce false sensing outputs towards the development of sensors with enhanced selectivity and sensitivity. Our goal is to elucidate the mechanisms governing the optical and electrical response of such engineered hybrid materials arising from the interaction between the organic functional molecule component and the inorganic nanocrystal core component. Establishment of component-function relationships will lead to disruptive new knowledge that will impact on optical and electrical sensors technologies.
Coordinator
University College Cork, National University Of Ireland, Cork (Eire)
Other participants
ALMA MATER STUDIORUM-UNIVERSITA DI BOLOGNA
- Dip. di Chimica "G. Ciamician"
- Resp. Scientifico: Prof. Alberto Credi
Mildendo Gesellschaft Fuer Mikrofluidische Systeme Mbh (Germany)
Cellix Limited (Eire)
Universitaet Basel (Switzerland)
Scriba Nanotecnologie Srl (Italy)
Universitat De Valencia (Spain)
The University Of Birmingham (UK)
Technische Universitaet Muenchen (Germany)
Start date 01/04/2011
End date 31/03/2014
Duration 36 months
Project Reference 263091
Project cost 3.979.357,07 Euro
Project Funding 3.000.000 Euro
Area FP7- COOPERATION – NMP
Subprogramme Area NMP – 2010 – 2.2-1: Organic-inorganic hybrids for electronic and photonics
Contract type Collaborative project