Periodic Reporting for period 1 - GrapheneCore2 (Graphene Flagship Core Project 2)
Periodo di rendicontazione: 2018-04-01 al 2020-03-31
During the final months of the period, many partners were affected by the corona virus crisis, which led to closings of laboratories in many European countries and caused difficulties in reaching some of the project's ambitious targets. This affected in particular the completion of many of the prototypes which rely on several partners' joint efforts during the entire project period and are therefore only finalized close to the end of the project.
One example of these actions is the authoritative white book on 2D Materials Production and Processing which was produced under the leadership of Mar Garcia Hernandez (leader of WP3 Enabling Materials) and involving 70 co-authors. During the first two months after its publication, the white book was downloaded some 27,000 times, which clearly shows the need for and interest in such a reference work.
In the work packages on Spintronics, WP2, and Wafer-Scale Integration, WP10, teams at RWTH and the Italian Institute of Technology developed CVD growth of very high-quality graphene for electronics applications.
In WP5, Biomedical technologies, the partners MCS and g.tec launched two new commercial products based on the work carried out in the work package on graphene-based FET technology for measuring electrical signals in and on the surface of the brain. These are the first products developed by the flagship in the area of biomedical technologies.
In WP7 Electronic Devices, researchers at TU Wien, AMO GmbH and University of Pisa have demonstrated the world's first integrated amplifier based on 2D materials and compatible with flexible substrates. It outperforms competing technologies by a large margin and incorporates many individual components with a high degree of reproducibility, which is a crucial requirement for components integrated in complicated circuits such as operational amplifiers. As technologies mature, the issue of reproducibility and manufacturability is becoming more prominent –breakthroughs in this direction include the quality monitoring and characterisation techniques based on terahertz measurements developed in WP7 by the Technical University of Denmark.
In WP8 Photonics and Optoelectronics, Politecnico of Milan and collaborators have developed a prototype (TRL 4) of a compact coherent Raman microscope which can be used for detection of cancerous tumours in real time in operating theatres. This is an example of novel diagnostic tools exploiting GRMs in healthcare applications.
An example of combined structural and electrical uses of graphene is given by aerodynamic surfaces, where we showed a graphene-composite leading edge of an Airbus 350 horizontal rear stabilizer. Airbus, Nanesa and CNR in WP14 Composites have further demonstrated a graphene-based deicing/anti-icing system that is compatible with composite parts and can produce a heating effect of 13 kW/m2. This is an example of multifunctional composites that simultaneously take advantage of several of the superior properties of graphene.
In spearhead project 3, several partners under the leadership of University of Rome Tor Vergata have realized the world's first graphene-enabled solar farm which is currently operational in Crete. The facility, which comprises panels with power conversion efficiency in excess of 15%, is now undergoing long term tests.
Under the leadership of Varta, the fifth spearhead project has produced high energy coin cell batteries that exceed the state-of-the-art by 35% in terms of capacity (measured in milliampere hours) and 25% in terms of energy density (measured in milliwatt hours). The batteries have been successfully produced in an industrial production facility and are expected to be released to consumers when the market conditions are right.