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ACCORDs will develop an imaging-based characterization framework (ACCORDs framework) for the holistic correlative assessment of Graphene Family Materials (GFMs) as a representative of 2D nanomaterials (NMs) to assess and predict 2D NMs health and environmental risks. The ACCORDs framework will operationalise safe and sustainable by design (SSbD) strategies proposed in past or ongoing H2020 projects or within OECD by correlating low-, medium-, and high-resolution physico-chemical-biological imaging-based methods with non-imaging methods in a tiered approach. ACCORDs will deliver the ACCORDs framework and user guidance, new imaging-based characterisation methods (3-6 methods), reference in vitro tests (up to three new tests), new reference 2D NMs (up to three) for different matrices, a new minimum information reporting guideline for FAIR data sharing and reuse of images as well as an atlas with reference images for diagnostics of compromised safety of GFMs / GFM products. The new guidelines and standard proposals will be submitted to standardisation bodies to allow creation of regulatory ready products. The novelty of ACCORDs is in translating the principles of medical imaging-based diagnostics to 2D material hazard diagnostics. ACCORDs will accelerate industrial sectors in the area of aviation, marine construction, drone production, flexible electronics, photovoltaics, photocatalytics and print inks-based sensors. The value ACCORDs proposes to the graphene industry are practical, easy, imaging-based tools for GFM quality monitoring next to the production line with a possibility to be correlated with advanced high-resolution imaging characterization methods in case hazard i.e. deviation from controls (benchmark values) are diagnosed. The ACCORDs framework and tools will contribute to the European Green Deal by addressing the topic: “Graphene: Europe in the lead” and to a new European strategy on standardization, released on 2nd February, 2022.

By advancing breakthrough research on LOHC technologies, UnLOHCked aims at developing a radically disruptive, versatile and scalable LOHC-dehydrogenation plant. Firstly, highly active and stable catalysts without critical raw materials will be developed for reducing LOHC dehydrogenation at moderate temperatures. Secondly, an SOFC-system will be developed to be thermally integrated with the dehydrogenation process. The heat demand of the dehydrogenation unit will be fully covered by the fuel cell, while generating electric power. The surplus of hydrogen is exported. These innovative systems fully integrated will allow significant increase of overall efficiency (>50%) to hydrogen and electric power production from LOHC. Three industry partners, HERAEUS, HYGEAR and FRAMATOME, will collaborate with four universities and research centres, the University of Bilbao (Spain), CEA, CNRS-Lyon and North-West University of South Africa to develop scalable prototype system at TRL 5, validating the performance of the technology during at least 500 h. The ambition is to demonstrate the feasibility of a fully CO2-free dehydrogenation process for large-scale production of hydrogen (100-1,000 t H2/d) and electricity with competitive prices (hydrogen carrier delivery cost <2.5€/kg). Thus converting CO2-free LOHC to electricity and hydrogen instead of using NG or LPG as heat source. The UnLOHCked approach is clean & circular: it decreases energy consumption, does not use noble metals while generating CO2-free hydrogen and electricity. Techno-economic studies will demonstrate the potential of the technology to both supply hydrogen and renewable electricity to decarbonise the EU economy and to open-up hydrogen transportation by LOHC. FRAMATOME, HYGEAR AND HERAEUS will support the consortium preparing for fast market entry after the project.

Liquid Organic Hydrogen Carriers (LOHC), consisting on a reversible transformation catalytically activated of a pair of stable liquid organic molecules integrated on hydrogenation/dehydrogenation cycles, are attractive due to their ability to store safely large amounts of hydrogen (up to 7 %wt or 2.300 KWh/ton) during long time and release pure hydrogen on demand. Proof of concept and some commercial solutions exist but still suffer from high cost and energy needed to facilitate catalytic reactions. In order to reduce the system cost for LOHC technology to 3 €/Kg for large scale applications SherLOHCk project targets joint developments consisting on :i) highly active and selective catalyst with partial/total substitution of PGM and thermo-conductive catalyst support to reduce the energy intensity during loading/unloading processes: ii) novel catalytic system architecture ranging from the catalyst to the heat exchanger to minimize the internal heat loss and to increase space-time-yield and iii) novel catalyst testing, system validation and demonstration in demo unit (>10 kW, >200h); to drastically improve their technical performances and energy storage efficiency of LOHCs: A combination of challenges for the catalyst material, catalyst system and their related energy storage capabilities will constitute the core of a catalyst system for LOHC, that will be validated first at a lab scale, then in a demo unit > 10kW. As a whole they will enable the reduction of Energy intensity during loading/unloading processes, a higher efficiency and increased lifetime. Technological, economical and societal bottlenecks are considered to determine the economic viability, balance of energy and the environmental footprint of novel catalyst synthesis route. Scale-up of the obtained solutions will be carried out together with technology comparison with other hydrogen logistic concepts based on LCA and TCO considerations to finally improve economic viability of the LOHC technology.

"BAQONDE (Boosting the Use of African Languages in Education. A Qualified Organized Nationwide DEvelopment Strategy for South Africa) represents a EU-SA well-defined collaborative response to the established national priority for CB projects ""The development of African Languages"". Departing from a rigorous need analysis that certified the dominant/detrimental role of English as the main language of instruction, BAQONDE aims to capacitate academic staff at HEIs to develop multilingual pedagogical skills that will enable the development of African languages as MoI at the tertiary level. The outputs of BAQONDE will contribute to develop a coordinated national strategy through the establishment of African Language Development Units (ALDUs) at each SA partner HEI. ALDUs will:1.Develop and implement a training program (including SA-EU mobilities) for a core group of lecturers from different disciplines to master context-relevant multilingual pedagogies2.Lead the production of digital subject-relevant multilingual materials for lecturers and students. These resources will be accessible from the project website to optimize the production/usage of materials in different disciplines/languages and harmonize multilingual teaching standards3.An inter-institutional Network of ALDUs will be established with the purpose of coordinating efforts, sharing resources and good practices in order to guarantee a culture of quality during the project and after its subsequent expansionBy fostering a culture of quality and coordinated cooperation, BAQONDE seeks to generate a major short-term impact in the teaching-learning process that will enable a greater long-term impact with far-reaching implications: the intellectualization of previously marginalized languages. This is in line with both the priorities of the country and the principles of equity, as it entails a better assimilation of contents and a greater development of professional competences by L1 African (Bantu) students."