The fuel cells and hydrogen (FCH) industry has made considerable progress toward market deployment. However existing legal framework and administrative processes (LAPs) – covering areas such as planning, safety, installation and operation – only reflect use of incumbent technologies. The limited awareness of FCH technologies in LAPs, the lack of informed national and local administrations and the uncertainty on the legislation applicable to FCH technologies elicit delays and extra-costs, when they do not deter investors or clients. This project aims at tackling this major barrier to deployment as follows: • Systematically identifying and describing the LAPs applicable to FCH technologies in 18 national legal systems as well as in the EU proper legal system. • Assessing and quantifying LAP impacts in time and/or resource terms and identify those LAP constituting a legal barrier to deployment. • Comparing the 18 countries to identify best and bad practices • Raising awareness in the countries where a LAP creates a barrier to deployment. • Advocating targeted improvements in each of 18 countries + EU level • It will make all this work widely available through: (1) A unique online database allowing easy identification, description and assessment of LAPs by country and FCH application. (2) Policy papers by applications and by country with identification of best practice and recommendations for adapting LAP. (3) A series of national (18) and European (1) workshops with public authorities and investors. HyLAW sets up a National Association Alliance not just for the duration of the project, but for the long term consolidation of the sector under a single unified umbrella. By bringing together these national associations and all of Hydrogen Europe’s members, it’s the first time ever that the entire European FCH sector is brought together with a clear and common ambition.

Heavy-duty vehicles account for about 25% of EU road transport CO2 emissions and about 6% of total EU emissions. In line with the Paris Agreement and Green Deal targets, Regulation (EU) 2019/1242 setting CO2 emission standards for HDVs (from August 14, 2019) forces the transition to a seamless integration of zero-emission vehicles into fleets. In line with the European 2050 goals ESCALATE aims to demonstrate high-efficiency zHDV powertrains (up to 10% increase) for long-haul applications that will provide a range of 800 km without refueling/recharging and cover at least 500 km average daily operation (6+ months) in real conditions. ESCALATE will achieve this by following modularity and scalability approach starting from the β-level of hardware and software innovations and aiming to reach the γ-level in the first sprint and eventually the δ-level at the project end through its 2 sprint-V-cycle. ESCALATE is built on the novel concepts around 3 main innovation areas, which are: i) Standardized well-designed, cost effective modular and scalable multi-powertrain components; ii) Fast Fueling & Grid-friendly charging solutions; and iii) Digital Twin (DT) & AI-based management tools considering capacity, availability, speed, and nature of the charging infrastructures as well as the fleet structures. Throughout the project lifetime, 5 pilots, 5 DTs and 5 case studies on TCO (with the target of 10% reduction), together with their environmental performance via TranSensusLCA will be performed. The ultimate goal is to develop well-designed modular building blocks with a TRL7/8 based on business model innovations used for 3 types of zHDVs {b-HDV,f-HDV,r-HDV}. Furthermore, 3 white papers will be produced, one of which will contribute defining the pathway for reducing well-to-wheel GHG emissions from HDVs based on results and policy assessments.

The overall objective of the ANIONE project is to develop a high-performance, cost-effective and durable anion exchange membrane water electrolysis technology. The approach regards the use of an anion exchange membrane (AEM) and ionomer dispersion in the catalytic layers for hydroxide ion conduction in a system operating mainly with pure water. This system combines the advantages of both proton exchange membrane and liquid electrolyte alkaline technologies allowing the scalable production of low-cost hydrogen from renewable sources. The focus is on developing advanced short side chain Aquivion-based anion exchange polymer membranes comprising a perfluorinated backbone and pendant chains, covalently bonded to the perfluorinated backbone, with quaternary ammonium groups to achieve conductivity and stability comparable to their protonic analogous, and novel nanofibre reinforcements for mechanical stability and reduced gas crossover. Hydrocarbon AEM membranes consisting of either poly(arylene) or poly(olefin) backbone with quaternary ammonium hydroxide groups carried on tethers anchored on the polymeric backbone are developed in parallel. The project aims to validate a 2 kW AEM electrolyser with a hydrogen production rate of about 0.4 Nm3/h (TRL 4). The aim is to contribute to the road-map addressing the achievement of a wide scale decentralised hydrogen production infrastructure with the long-term goal to reach net zero CO2 emissions in EU by 2050. To reach such objectives, innovative reinforced anion exchange membranes will be developed in conjunction with non-critical raw materials (CRMs) high surface area electro-catalysts and membrane-electrode assemblies. Cost-effective stack hardware materials and novel stack designs will contribute to decrease the capital costs of these systems. After appropriate screening of active materials, in terms of performance and stability, in single cells, these components will be validated in an AEM electrolysis stack operating with high differential pressure and assessed in terms of performance, load range and durability under steady-state and dynamic operating conditions. The proposed solutions can contribute significantly to reducing the electrolyser CAPEX and OPEX costs. The project will deliver a techno-economic analysis and an exploitation plan for successive developments with the aim to bring the innovations to market. The consortium comprises an electrolyser manufacturer, membrane, catalysts and MEAs suppliers.