The R&I PEERS project will be based on the concept of gender equality, that can be expressed as “women and men enjoy the same status and have equal opportunity to realize their full human rights and potential to contribute to national, political, economic, social and cultural development, and to benefit from the results”.

This project is the third stage of the EC-funded part of the Graphene Flagship. It builds upon the results achieved in the ramp-up phase (2013 - 2016) and the first core project (2016 - 2018), and covers the period April 2018 - March 2020.

Thin films of hybrid materials engineered at the molecular scale can enable breakthroughs in several economically and socially relevant technological application areas including packaging & encapsulation, electronics, batteries and biomedical applications. With self-limiting binary reactions, Molecular Layer Deposition (MLD) is the ideal deposition technique for growing ultra-thin, uniform, conformal hybrid films with precise and flexible control over the film thickness and molecular-scale chemical composition. The key objective of HYCOAT is to create a group of exceptionally well-trained young researchers who have a deep understanding of all aspects of MLD technology, as well as broad vision on the application potential of hybrid coatings.

QuESTech (Project ID: 766025) is a consortium of 7 leading European research laboratories and 2 high-tech companies. Supported by the European Community, QuESTech will provide a challenging, state-of-the-art training for young researchers in the general field of experimental, applied, and theoretical quantum electronics. The main scientific topics include spintronics, molecular electronics, single electronics, transport in low-dimensional structures, and quantum thermodynamics.

We propose to establish Plasmon -enhanced Terahertz Electron Paramagnetic Resonance spectroscopy and scanning microscopy as a unique Electron Paramagnetic Resonance (EPR) platform for high-sensitivity local analysis of paramagnetic organic and inorganic species and materials. Here, we will deliver novel hardware and infrastructure providing ground-breaking innovation in the magnetic sensing and imaging.

Understanding radiation effects on different materials is of paramount importance for many scientific and technological fields like those related to nuclear energy, space industry, laser- and ion-based materials processing and therapeutic applications. The particular case of radiation effects on pure and mixed water ice is very important in Astrochemistry and Prebiotic Chemistry, being water ice present in cosmic dust grains and on the surface of many bodies in the Solar System like asteroids and several satellites (e.g. Europa, Callisto and Ganymede).