CORNET is an ambitious project that develop a unique EU Open Innovation Environment (OIE), that cover the triangle of manufacturing, modelling and experimentation for the optimization the Organic/Large Area Electronic (OE) nanomaterials, materials behavior and nano-devices (OPVs, PPVs, OLEDs) manufacturing of R2R printing & gas transport (OVPD) processes, to validate materials models based on experimentation and fabricate tailored OE devices and systems for demonstration to industrial applications (e.g. automotive, greenhouses). CORNET will develop a sustainable OIE Platform and OIE Database for documentation of citable & industrially accepted protocols for OE material and device characterization, modelling and manufacturing. CORNET strategy will establish strong links and clustering with existing EU clusters (as EMMC, EMCC, EPPN), end-user & industrial associations, and EU networks to increase the speed of OE materials/device development and industry uptake, maximize the acceptance of the OIE and push-through standards for adoption by industry worldwide. The CORNET main objectives are to: 1. Develop an effective OIE with world-class experts in Manufacturing, Multiscale Characterization & Modelling, connected to EU clusters, and create a reliable database with citable protocols with contribution to Standards 2. Multiscale Characterization & Modelling to Optimize OE nanomaterials and devices fabrication and Models Validation 3. Optimize the nano-device Manufacturing of OPVs, PPVs, OLEDs by Printing (R2R, S2S) and OVPD Processes 4. Fabricate Tailored Devices, Systems and Demonstrate to industrial applications (e.g. automotive, greenhouses) CORNET has developed a strategic plan for the clustering activities with more than 800 existing related bodies, a Business Plan for the continuation of the OIE beyond the project and the Innovation Management, IPR and legal support services to protect generated foreground and to enable its adoption by the EU research & industrial communities.

Q-SENSE will promote international and inter-sector collaboration for the advancement of science and the development of innovation in the area of cold atom quantum sensors. In particular it fosters a shared culture of research and innovation that turns the Nobel-prize winning ideas of cold atom research and precision measurement (Nobel prizes 1997 and 2005) into innovative products. In particular, we bring together a synergetic network of the world leaders in optical clocks and atom interferometers with technology translators and end user applicants to promote space and terrestrial applications of optical clocks and cold atom gravity sensors with an additional eye on implications on policies via the JRC. Our research and innovation programme will deliver knowledge exchange around a technology demonstrator for a space optical clock, development plans for atom interferometer satellite missions, an open source toolbox for simulations of atom interferometer performance in real-world applications and outreach to over 70 companies and the public raising awareness of the potential of optical clocks and cold atom gravimeters for economic and societal benefits, such as in global water monitoring, humanitarian de-mining, satellite navigation and broadband communication. Q-SENSE will enhance the skills of research- and innovation-related human resources in our partner organisations to work seamlessly across sectors and provide new career perspectives in the emerging area of commercial quantum technologies.

A failure to quantitatively control adhesion costs billions of euros each year in failed components, suboptimal product performance and life-threatening infections. Nano-enabled and bio-inspired products offer practical solutions to overcome adhesion and friction problems in these application areas. Current tools and methodologies, however, have so far failed to produce any standardised interpretation of adhesion data linking nanoscale adhesion to the macroscopic data. OYSTER uses contact mechanics to bridge adhesion data at multiple length scales and link interfacial adhesion to physicochemical properties. OYSTER brings Europe’s first-class laboratories and SMEs to take existing nanoscale characterisation technologies towards widespread utilisation in process optimisation and model validation. OYSTER achieves this by sharing metadata in an Open Innovation Environment, where new paradigms of multi-scale contact mechanics are validated on selected application oriented reference materials through continuous interaction with the European Materials Characterisation Council (EMCC). This way, OYSTER generates wider agreement over adhesion measurement protocols by multimodal Atomic Force Microscopy and high-speed nanoindentation. Tools and methodologies at Technology Readiness Level (TRL) 4 will be progressed to TRL 6 through unambiguous, standardised, quantitative measurements of adhesion from nano- to macro-scale. Nano-patterned wear resistant surfaces and chemically/topologically functionalised soft contact lenses will show case nano-enabled and bioinspired products for significant market impact. In this way, OYSTER implements the triangle of modelling, characterisation and manufacturing to the wider context of industrial exploitation specially through small and medium enterprises, stakeholders’ networks such as EMCC, European Materials Modelling Councils (EMMC) and European Pilot Project Network (EPPN), and international standard organisations.