ERC FUNDED PROJECTS

The suite of graphene’s unique properties and applications can be enormously enhanced by its functionalization. As non-covalently functionalized graphenes do not target all graphene’s properties and may suffer from limited stability, covalent functionalization represents a promising way for controlling graphene’s properties. To date, only a few well-defined graphene derivatives have been introduced. Among them, fluorographene (FG) stands out as a prominent member because of its easy synthesis and high stability. Being a perfluorinated hydrocarbon, FG was believed to be as unreactive as the two-dimensional counterpart perfluoropolyethylene (Teflon®). However, our recent experiments showed that FG is not chemically inert and can be used as a viable precursor for synthesizing graphene derivatives. This surprising behavior indicates that common textbook grade knowledge cannot blindly be applied to the chemistry of 2D materials. Further, there might be specific rules behind the chemistry of 2D materials, forming a new chemical discipline we tentatively call 2D chemistry. The main aim of the project is to explore, identify and apply the rules of 2D chemistry starting from FG. Using the knowledge gained of 2D chemistry, we will attempt to control the chemistry of various 2D materials aimed at preparing stable graphene derivatives with designed properties, e.g., 1-3 eV band gap, fluorescent properties, sustainable magnetic ordering and dispersability in polar media. The new graphene derivatives will be applied in sensing, imaging, magnetic delivery and catalysis and new emerging applications arising from the synergistic phenomena are expected. We envisage that new applications will be opened up that benefit from the 2D scaffold and tailored properties of the synthesized derivatives. The derivatives will be used for the synthesis of 3D hybrid materials by covalent linking of the 2D sheets joined with other organic and inorganic molecules, nanomaterials or biomacromolecules.

1 831 103 €

Start date: 2016-06-01, End date: 2022-05-31

Hepatitis B virus (HBV) infections remain a major public health issue worldwide. Over 350 -400 million people are chronically infected by HBV, and about 1 million people die each year from the complications of this infection (cirrhosis and hepatocellular carcinoma) with a consequent hefty economic impact on national health systems. This led the World Health Organization to recognise HBV infection as a key priority and adopt the global health sector strategy to eliminate viral hepatitis, with a target of reducing new infections by 90% and mortality by 65% by 2030. The risk of developing a chronic infection in healthy adults is due to a weaker, dysfunctional and narrowly focused CD8+ T cell response. Since the mechanisms underlying HBV persistence are not fully elucidated, current treatments (antiviral drugs and Interferon) aim to reduce the development of liver disease, while a definitive treatment for curing this infection is not yet available on the market. Within the ERC Consolidator Grant 725038 “FATE”, we recently characterized the mechanisms behind the ineffective CD8+ T cell response towards HBV, demonstrating the potential efficacy of interleukin-2 (IL-2) – a cytokine – to reactivate it, thus achieving antiviral activity. This discovery, jointly with our proprietary third-generation, self-inactivating lentiviral vectors (LVs) that allow selective hepatocellular expression of IL-2, pave the way to single-dose gene therapy-based approach, a potential functional cure against chronic hepatitis B. 2LIVEr project intends to optimize and further validate our novel therapeutic approach from both a technical and commercial standpoint, moving from TRL3 to TRL4, thus fastening the roadmap towards the market.

150 000 €

Start date: 2020-07-01, End date: 2021-12-31

Photonics, in recognition of its strategic significance and pervasiveness throughout many industrial sectors, has been identified as one of the Key Enabling Technologies for Europe. Photonics in combination with quantum information science has great potential to facilitate, transform and innovate future technologies for the better. The Proof of Concept (PoC) project intends to contribute to this by developing and testing a communication platform prototype, comprised of single photon detectors, which are efficiently coupled to single mode fibers using an innovative laser written device. This enables the integration of single photon detectors on innovative glass waveguides. These glass integrated photonic circuits offer excellent specifics for on-chip quantum optics implementations in terms of scattering losses, offering flexibility of the waveguide geometry and ensuring high coupling efficiency with optical fibers. The device developed and tested in the PoC, directly addresses a market need for an integrated and efficient on-chip communication systems. Current available systems have limitations involving high costs, complex production, and inefficient coupling of detectors to optical fibers. The proposed platform will offer 1.) a simplified production process, 2.) high optical fiber coupling efficiency 3.) improved performance levels, 4.) high cost efficiency, and 5.) compactness. Such systems can be applied in a wide range of communication and non-communication applications, such as free-space optical communication, quantum communication, quantum cryptography, DNA sequencing, single molecule detection and material analysis. Moreover, the future commercialisation of quantum computing is expected to create a vast demand for these communication systems. In addition to the technology PoC, the project carries out IPR strategy considerations through patenting actions, determines the market potential, seeks market feedback, and plans for post-PoC commercialisation paths.

150 000 €

Start date: 2016-02-01, End date: 2017-07-31

How does the inside of the proton look like? What generates its spin?
3DSPIN will deliver essential information to answer these questions at the frontier of subnuclear physics. At present, we have detailed maps of the distribution of quarks and gluons in the nucleon in 1D (as a function of their momentum in a single direction). We also know that quark spins account for only about 1/3 of the spin of the nucleon. 3DSPIN will lead the way into a new stage of nucleon mapping, explore the distribution of quarks in full 3D momentum space and obtain unprecedented information on orbital angular momentum. Goals 1. extract from experimental data the 3D distribution of quarks (in momentum space), as described by Transverse-Momentum Distributions (TMDs); 2. obtain from TMDs information on quark Orbital Angular Momentum (OAM). Methodology 3DSPIN will implement state-of-the-art fitting procedures to analyze relevant experimental data and extract quark TMDs, similarly to global fits of standard parton distribution functions. Information about quark angular momentum will be obtained through assumptions based on theoretical considerations. The next five years represent an ideal time window to accomplish our goals, thanks to the wealth of expected data from deep-inelastic scattering experiments (COMPASS, Jefferson Lab), hadronic colliders (Fermilab, BNL, LHC), and electron-positron colliders (BELLE, BABAR). The PI has a strong reputation in this field. The group will operate in partnership with the Italian National Institute of Nuclear Physics and in close interaction with leading experts and experimental collaborations worldwide. Impact Mapping the 3D structure of chemical compounds has revolutionized chemistry. Similarly, mapping the 3D structure of the nucleon will have a deep impact on our understanding of the fundamental constituents of matter. We will open new perspectives on the dynamics of quarks and gluons and sharpen our view of high-energy processes involving nucleons.

1 509 000 €

Start date: 2015-07-01, End date: 2020-12-31