Belgium

A combined density functional theory and molecular dynamics approach is employed to study modifications of graphene at atomistic level for better H2 storage. The study reveals H₂ desorption from hydrogenated defective graphene structure V₂₂₂ to be exothermic. H₂ adsorption and desorption processes are found to be more reversible for V₂₂₂ as compared to pristine graphene. Our study shows that V₂₂₂ undergoes brittle fracture under tensile loading similar to the case of pristine graphene. The tensile strength of V₂₂₂ shows slight reduction with respect to their pristine counterpart which is attributed to the transition of sp2 to sp3-like hybridization. The study also shows that the V₂₂₂ structure is mechanically more stable than the defective graphene structure without chemically adsorbed hydrogen atoms. The current fundamental study thus reveals the efficient recovery mechanism of adsorbed hydrogen from V₂₂₂ and paves the way for the engineering of structural defects in graphene for H₂ storage.

Fuel cell electric vehicles (FCEVs) are zero tailpipe emission vehicles. Their large-scale deployment is expected to play a major role in the de-carbonization of transportation in the European Union (EU) and is therefore an important policy element at EU and Member State level.<br/>For FCEVs to be introduced to the market a network of hydrogen refuelling stations (HRS) first has to exist. From a technological point of view FCEVs are ready for serial production already: Hyundaiand Toyota plan to introduce FCEVs into key markets from 2015 and Daimler Ford and Nissan plan to launch mass-market FCEVs in 2017.<br/>At the moment raising funds for building the hydrogen refuelling infrastructure appears to be challenging.<br/>This study explores options for financing the HRS rollout which facilitate the involvement of private lenders and investors. It  presents a number of different financing options involving public-sector bank loans funding from private-sector strategic equity investors commercial bank loans private equity and funding from infrastructure investors. The options outline the various requirements forn accessing these sources of funding with regard to project structure incentives and risk mitigation. The financing options were developed on the basis of discussions with stakeholders in the HRS rollout from industry and with financiers.<br/>This study was prepared by Roland Berger in close contact with European Investment banks and a series of private banks.<br/>This study explores in details the business cases for HRS in Germany and UK. The conclusion can be easily extrapolate to other countries.

This report provides an outlook for jointly achieving a commercialisation pathway.<br/>Building on the findings of the 2012 FCH JU technology study on alternative powertrains for urban buses this report provides an assessment of the commercialisation pathway from an operational perspective. It reflects the actual situation in which operators deploy large scale demonstration projects in the next years from a rather conservative angle and argues why it makes sense to deploy FC buses now. The insights are based on first-hand data and assessments of the coalition members from the hydrogen and fuel cell industry as well as local governments and public transport operators in Europe.

Fuel cell electric vehicles (FCEV) are developing quickly from passenger vehicles to trucks or fork-lifts. Policymakers are supporting an ambitious strategy to deploy fuel cell electrical vehicles with infrastructure as hydrogen refueling stations (HRS) as the European Green deal for Europe. The hydrogen fuel quality according to international standard as ISO 14687 is critical to ensure the FCEV performance and that poor hydrogen quality may not cause FCEV loss of performance. However the sampling system is only available for nozzle sampling at HRS. If a FCEV may show a lack of performance there is currently no methodology to sample hydrogen fuel from a FCEV itself. It would support the investigation to determine if hydrogen fuel may have caused any performance loss. This article presents the first FCEV sampling system and its comparison with the hydrogen fuel sampling from the HRS nozzle (as requested by international standard ISO 14687). The results showed good agreement with the hydrogen fuel sample. The results demonstrate that the prototype developed provides representative samples from the FCEV and can be an alternative to determine hydrogen fuel quality. The prototype will require improvements and a larger sampling campaign.

In the sixth episode titled Exploring Opportunities for EU-Canada Hydrogen Cooperation our CEO Jorgo Chatzimarkakis discusses with John Risley Charmain and CEO of CFFI Ventures and Stefan Kaufmann former Innovation Commissioner for Green Hydrogen of the German government and now adviser to Thyssenkrupp. In the discussion about hydrogen market and technology's development in Canada and in Germany the businessman and the policy advisor bring two different geographical and expertise perspectives about the topic. Taking into consideration the US' IRA Canada's investments in the hydrogen sector and the European plans regarding H2Global and the Hydrogen Bank our guests compare North America and the EU. They debate over the economic and financial support the industry needs to invest in the green energy transition and the role global cooperation and competition play.

From navigating the rainbow of colours to the lack of consensus in establishing a common taxonomy the labelling and definition of green or renewable hydrogen presents a growing challenge. In this context carbon taxonomy is understood through five critical aspects: carbon intensity temporal and geographical correlation additionality of renewable energy generation and different system boundaries in Life Cycle Assessment (LCA). This study examines the effect of carbon taxonomy on the design and operation of Power-to-Gas (PtG) systems for renewable hydrogen production including the electricity supply portfolio via Power Purchase Agreements (PPA) and grid-connected electrolysis. To this end an optimisation model combining energy system modelling and LCA is developed and then applied to a case study in the Japanese context. The importance of the PPA portfolio in securing cheap and low-carbon electricity to produce hydrogen is addressed. To support this evaluation process an eco-efficiency metric is introduced and proved to be a comprehensive tool for evaluating renewable hydrogen production. Regarding carbon taxonomies the findings emphasize additionality as the key determinant factor followed by temporal correlation and the definition of carbon intensity thresholds. The application of a cradle-togate LCA boundary influenced the cabron intensity accounting playing an unexpected role on the design and optimal PtG dispatch strategy.

Purpose: The technology and market module of the FCHO presents a range of statistical data as an indicator of the health of the sector and the progress in market development over time. https://www.fchobservatory.eu/observatory/technology-and-market Scope: Fuel cell shipment data is presented on a global basis. Other sections of the technology and market chapter (HRS data and FCEV data) are presented on a European basis. The report spans January 2020 – December 2020. Key Findings: COVID-19 has without doubt impacted the deployment of fuel cells and hydrogen in 2020 compared to industry expectations: Global Fuel Cell shipments > 1.3 GW Europe Fuel Cell shipments up to 148.6 MW Europe HRS in operation or under construction 162 FCEVs up 41% to 2774

Purpose: The policy module of the FCHO presents an overview of EU and national policies across various hydrogen and fuel cell related sectors. It provides a snapshot of the current state of hydrogen legislation and policy. https://www.fchobservatory.eu/observatory/policy-and-rcs/eu-policies https://www.fchobservatory.eu/index.php/observatory/policy-and-rcs/nationalpolicies Scope: While FCHO covers 38 entities around the world due to the unavailability of some data at the time of writing this report covers 34 entities. The report reflects data collected January 2021 – May 2021. Key Findings: Hydrogen policies are relatively commonplace among European countries but with large differences between Member States. EU hydrogen leaders do not lag behind global outliers such as South Korea or Japan.

With the adoption of the EU Climate Law in 2021 the EU has set itself a binding target to achieve climate neutrality by 2050 and to reduce greenhouse gas emissions by 55 percent compared to 1990 levels by 2030. To support the increased ambition the EU Commission adopted proposals for revising the key directives and regulations addressing energy efficiency renewable energies and greenhouse gas emissions in the Fit for 55 package. The heating and cooling (H&C) sector plays a key role for reaching the EU energy and climate targets. H&C accounts for about 50 percent of the final energy consumption in the EU and the sector is largely based on fossil fuels. In 2021 the share of renewable energies in H&C reached 23%.

Hydrogen is commonly used as feedstock in industrial processes and is regarded as a potential future energy carrier. However its reactivity and low density make it difficult to handle and store safely. Indoor hydrogen dispersion can cause a fire or explosion hazard if encountering an ignition source. Safety practices often use time expensive modelling techniques to estimate risk associated with hydrogen. A neural network based surrogate model could efficiently replace Computational Fluid Dynamics (CFD) modelling in safety studies. To lower the dimensionality of this surrogate model a dimensional analysis based on Buckingham’s Pi-theorem is proposed. The dimensional analysis examines stratified filling and highlights the functional parameters involved in the process. Stratified filling occurs for buoyancy dominated releases and is characterized by layers of decreasing concentration starting at the ceiling of the enclosure and developing towards the bottom. The study involves four dimensional cases that were simulated using Computational Fluid Dynamics (CFD) to demonstrate the usefulness of the proposed dimensionless time and dimensionless volume. The setup considered in this paper consists of a parallelepiped enclosure with standard atmospheric conditions a single release source and one pressure outlet to ensure constant pressure during the release. The results of the CFD simulations show a distinct pattern in the relation of hydrogen molar fraction and dimensionless time. The pattern depends on the dimensionless height of the measurement location. A five-parameter logistic (5PL) function is proposed to fit the data from the CFD models. Overall the paper provides insights into the functional parameters involved in the evolution of hydrogen mass fractions during stratified filling. It provides a nondimensional surrogate model to compute the evolution of the local concentrations of hydrogen during the development of stratification layers.

This report aims to summarise the status of the European hydrogen policies and standards landscape. It is based on the information available at the European Hydrogen Observatory (EHO) platform the leading source of data and information on hydrogen in Europe (EU27 EFTA and the UK) providing an overview of the European and national policies legislations strategies and codes and standards which impact the deployment of hydrogen technologies and infrastructures. The EHO database covers a total of 29 EU policies and legislations that directly or indirectly affect the development and deployment of hydrogen technologies. To achieve its net zero ambitions the EU started with cross-cutting strategies such as the EU Green Deal and the EU Hydrogen Strategy setting forward roadmaps and targets that are to be achieved in the near future. As a next step the EU has developed legislations such as those bundled in the Fit for 55 package to meet the targets they have put forward. The implemented legislations including funding vehicles and initiatives have an impact on the whole value chain of hydrogen including production transport storage and distribution and end-uses. At national level as of July 2023 63% of the European countries have successfully published their national strategies in the hydrogen sector while 6% of the countries are currently in the draft stage. Several European countries have strategically incorporated quantitative indicators within their national strategies outlining their targets and estimates across the hydrogen value chain. This deliberate approach reflects a commitment to providing clear and measurable goals within their hydrogen strategies. A target often used in the national strategies is on electrolyser capacity as an effort to enhance the domestic renewable hydrogen production. Germany took the lead with an ambitious goal of achieving 10 GW by 2030 followed by France (6.5 GW) and Denmark (4 - 6 GW). Other targets that some of the countries use in their strategies are on the number of hydrogen refuelling stations fuel cell electric vehicles and total (renewable) hydrogen demand. A few countries also have targets on renewable hydrogen uptake in industry and hydrogen injection limit in the transmission grid. To monitor the policies and legislation that are adopted on a national level across the hydrogen value chain a survey was launched with national experts which was validated by Hydrogen Europe. In total 28 European countries have participated to the survey. On production the survey revealed that 61% of country specialists report that their country provides support for capital expenditure (CAPEX) in the development of renewable or low-carbon hydrogen production plants. Moreover 7 countries also provide support for operational expenditure (OPEX). Furthermore 8 countries have instituted official 6 permitting guidelines for hydrogen production projects while 5 countries have enacted a legal act or established an agency serving as a single point of contact for hydrogen project developers. For transmission only two countries reported to provide support schemes for hydrogen injection. Several countries have policies in place that clearly define the hydrogen limit in their transmission grid for now and in the future ranging from 0.02% up to 15% while a few countries define within their policies the operation of hydrogen storage facilities. On end-use the majority of countries totalling 71% reported to have implemented support schemes aimed at promoting the adoption of hydrogen in the mobility sector. Purchase subsidies stand out as the predominant form of support for fuel cell electric vehicles (FCEVs) with implementation observed in 17 countries. In the context of support schemes for stationary fuel applications for heating or power generation only two countries have adopted such measures. A slightly larger group of four countries do provide support for the deployment of residential and commercial heating systems utilizing hydrogen. For hydrogen end-use in industry a total of 9 countries reported to provide support schemes with a major focus on ammonia production (8) and the chemicals industry (7). On the topic of technology manufacturing 7 countries have reported to have support schemes of which grants emerge as the mainly used method (4). Exploring the latest advancements into European codes and standards relevant to the deployment of hydrogen technologies and infrastructures a total of 11 standards have been revised and developed between January 2022 and September 2023. This includes standards covering the following areas: 6 for fuel cell technologies 2 for gas cylinders 2 for road vehicles and 1 for hydrogen refuelling. Moreover 5 standards were published since September 2023 which will be added to the EHO database in its next update. This includes ISO/TS 19870:2023 which sets a methodology for determining the greenhouse gas emissions associated with the production conditioning and transport of hydrogen to consumption gate. This landmark standard which was unveiled at COP28 aims to act as a foundation for harmonization safety interoperability and sustainability across the hydrogen value chain.

Purpose: The policy module of the FCHO presents an overview of EU and national policies across various hydrogen and fuel cell related sectors. It provides a snapshot of the current state of hydrogen legislation and policy. Scope: This report covers 34 entities and it reflects data collected January 2022 – February 2022. Key Findings: Hydrogen policies are relatively commonplace among European countries but with large differences between member states. Mobility policies for FCEVs are the most common policy types. EU hydrogen leaders do not lag behind global outliers such as South Korea or Japan.

This report aims to summarise the status of the European hydrogen market landscape. It is based on the information available at the European Hydrogen Observatory (EHO) platform the leading source of data and information on hydrogen in Europe (EU27 EFTA and the UK) providing a full overview of the hydrogen market and the deployment of clean hydrogen technologies. As of the end of 2022 a total of 476 operational hydrogen production facilities across Europe boasting a cumulative hydrogen production capacity of approximately 11.30 Mt were identified. Notably the largest share of this capacity is contributed by key European countries including Germany the Netherlands Poland Italy and France which collectively account for 56% of the total hydrogen capacity. The hydrogen consumption in Europe has been estimated at approximately 8.23 Mt reflecting an average capacity utilisation rate of 73%. It's worth highlighting that conventional hydrogen production methods encompassing reforming by-product production from ethylene and styrene and by-product electrolysis collectively yield 11.28 Mt of hydrogen capacity. These conventional processes are distributed across 376 production facilities constituting 99.9% of the total production capacity in 2022. Throughout the year 2022 there were no newly commissioned hydrogen production facilities that integrated carbon capture technology into their operations. Additionally a notable presence of water electrolysis-based hydrogen production projects in Europe was identified. There was a total of 97 water electrolysis projects with 67 of them having a minimum capacity of 0.5 MW resulting in a cumulative production capacity of 174.28 MW. Furthermore 46 such projects were found to be under construction and are anticipated to contribute an additional 1199.07 MW of water electrolysis capacity upon becoming operational with the estimated timeframe ranging from January 2023 to 2025. A significant 87% of the total hydrogen production capacity in Europe is dedicated to onsite captive consumption indicating that it is primarily produced and used within the facility. The remaining 13% of capacity is specifically allocated for external distribution and sale characterizing what's known as merchant consumption. Despite the prevailing dominance of captive hydrogen production within Europe it's noteworthy that thousands of metric tonnes of hydrogen are already being traded and distributed across the continent. These transfers often occur through dedicated hydrogen pipelines or transportation via trucks. In 2022 an example of this growing trend was the hydrogen export from Belgium to the Netherlands which emerged as the single most significant hydrogen flow between European countries constituting a substantial 75% of all hydrogen traded in Europe. Belgium earned distinction as Europe's leading hydrogen exporter with 78% of the hydrogen that flowed between European countries originating 6 from its facilities. Conversely the Netherlands played a pivotal role as Europe's primary hydrogen importer accounting for an impressive 76% of the hydrogen imported into the continent. The rise of the clean hydrogen market in Europe coupled with the European Union's ambition to import 10 Mt of renewable hydrogen from non-EU sources by 2030 is expected to drive an increase in hydrogen flows both exports and imports among European countries. In 2022 the total demand for hydrogen in Europe was estimated to be 8.19 Mt. The biggest share of hydrogen demand comes from refineries which were responsible for 57% of total hydrogen use (4.6 Mt) followed by the ammonia industry with 24% (2.0 Mt). Together these two sectors consumed 81% of the total hydrogen consumption in Europe. Clean hydrogen demand while currently making up less than 0.1% of the overall hydrogen demand is notably driven by the mobility sector. Forecasts project an impressive growth trajectory in total hydrogen demand for Europe over the coming decades. Projections show a remarkable 127% surge from 2030 to 2040 followed by a substantial 63% increase from 2040 to 2050. Considering the current hydrogen demand there is a projected 51% increase until 2030. Throughout the three decades under examination the industrial sector is anticipated to maintain its predominant position consistently demonstrating the highest demand for hydrogen. However this conclusion refers to average values and variations that may exist. The total number of Hydrogen Fuel Cell Electric Vehicles (FCEV) registrations in Europe in 2022 was estimated at 1537 units. In comparison to the previous year the number of registrations increased by 31%. This surge in registrations has had a pronounced impact on the overall FCEV fleet's evolution in Europe which increased from 4050 units to 5570 (+38%). Notably passenger cars dominated the landscape constituting 86% of the total FCEV fleet. Exploring the latest advancements in hydrogen infrastructure across Europe in 2022 the hydrogen distribution network comprised spanning a total length of 1569 km. Within Europe the largest networks are situated in Belgium and Germany at 600 km and 400 km respectively. Of particular importance is the cross-border network of France Belgium and the Netherlands spanning a total of 964 km. To keep pace with the rising number of Fuel Cell Electric Vehicles (FCEVs) on European roads and promote their wider integration it is key to ensure sufficient accessibility to refuelling infrastructure. Consequently many countries are endorsing the establishment of hydrogen refuelling stations (HRS) so that they are publicly accessible on a nationwide scale. More recharging and refuelling stations for alternative fuels will be deployed in the coming years across Europe enabling the transport sector to significantly reduce its carbon footprint following the adoption of the alternative fuel infrastructure regulation (AFIR). Part of the regulation's main target is that hydrogen refuelling stations serving both cars and lorries must be deployed from 7 2030 onwards in all urban nodes and every 200 km along the TEN-T core network. Since 2015 the total number of operational and publicly accessible HRS in Europe has grown at an accelerated pace from 38 to 178 by the summer of 2023. Germany takes the lead having the largest share at approximately 54% of the total number of HRS with 96 stations currently operational. The majority of the HRS (89%) are equipped with 700 bar car dispensers. In 2022 the levelized production costs of hydrogen generated through Steam Methane Reforming (SMR) in Europe averaged approximately 6.23 €/kg H2. When incorporating a carbon capture system the average cost of hydrogen production via SMR in Europe increased to 6.38 €/kg H2. Additionally the production costs of hydrogen in Europe for 2022 utilizing grid electricity averaged 9.85 €/kg H2. Hydrogen production costs through electrolysis with a direct connection to a renewable energy source had an average estimated cost of 6.86 €/kg. As of May 2023 Europe's operational water electrolyser manufacturing capacity stands at 3.11 GW/year with an additional 2.64 GW planned by the end of 2023. Alkaline technologies make up 53% of the total capacity. Looking ahead to 2025 ongoing projects are expected to raise the total capacity to 7.65 GW/year. Fuel cell deployment in Europe has showed an increasing trend over the past decade. The total number of shipped fuel cells were forecasted on around 11200 units in 2021 and a total capacity of 190 MW. The most significant increase in capacity occurred between 2018 and the forecast of 2021 (+148.8 MW).

Hydrogen refueling stations (HRS) can cause a significant fraction of the hydrogen refueling cost. The main cost contributor is the currently used mechanical compressor. Electrochemical hydrogen compression (EHC) has recently been proposed as an alternative. However its optimal integration in an HRS has yet to be investigated. In this study we compare the performance of a gaseous HRS equipped with different compressors. First we develop dynamic models of three process configurations which differ in the compressor technology: mechanical vs. electrochemical vs. combined. Then the design and operation of the compressors are optimized by solving multi-stage dynamic optimization problems. The optimization results show that the three configurations lead to comparable hydrogen dispensing costs because the electrochemical configuration exhibits lower capital cost but higher energy demand and thus operating cost than the mechanical configuration. The combined configuration is a trade-off with intermediate capital and operating cost.

The aim of this project is to identify the investment requirements for energy infrastructure across each TEN-E infrastructure category as well as for non-TEN-E electricity transmission and distribution infrastructure in order to enable a decarbonised economy in the EU. It also evaluates the need for EU financial support and explores possible forms of EU funding to address the identified needs within the scope of this study's assessment.

This report supports the European Commission (DG ENER) in the design and implementation of a European import auction for renewable hydrogen and its derivatives under the European Hydrogen Bank (EHB). The EHB aims to contribute to the EU's climate neutrality goal by 2050. While domestic auctions have already been launched under the EHB its international leg focusing on renewable fuels of non-biological origin (RFNBO) imports from third countries remains to be designed. This report offers strategic recommendations based on hydrogen market analyses the assessment of existing and planned hydrogen auction schemes in Europe and beyond as well as preliminary considerations on auction design. The analysis highlights the potential for hydrogen imports from regions like North America Australia Latin America and the MENA region. It includes concrete case studies on both pipeline-based imports of pure hydrogen and ship-based imports of key derivatives (ammonia methanol and synthetic aviation fuels (eSAF) to reflect Member State preferences and provides a concrete starting point for further defining import auctions. Priority considerations for auction design include ensuring fair competition between domestic production and imports addressing geopolitical risks and achieving cost efficiency. The case studies serve as a flexible blueprint for implementing EHB import auctions considering Member State interests and aligning with the EU's broader objectives.

Renewing a vision for European aviation: Europe today leads the world in civil aviation and air traffic management (ATM). This success should not be taken for granted particularly as the sector undergoes decarbonisation and digitalisation in today’s challenging geopolitical context. Significant value is at stake and capturing this value – for the sake of Europe’s competitiveness sustainability and sovereignty – is contingent on substantial investment in aviation research and innovation (R&I) and support to market uptake of new technologies to avoid the “valley of death” between technological development and product entry-into-service. Aviation is a major socio-economic contributor to Europe: The aviation industry is a vital component of Europe’s economy contri buting significantly to jobs gross domestic product (GDP) and trade. Overall the European aviation sector supports 15 million jobs and contributes EUR 1.1 trillion to European economic activity. The aviation sector is also critical to the EU single market European integration and global connectivity. It drives innovation and enhances Europe’s global influence and security through its combined focus on sustainability and competitiveness. The importance of aviation in achieving these fundamental goals for Europe is underscored by the findings of the Draghi report.

The impact of the HyResponder project on the training of responders in 10 European countries is described. An overview is presented of training activities undertaken within the project in Austria Belgium Czech Republic France Germany Italy Norway Spain Switzerland and the United Kingdom. National leads with training expertise are given and the longer-term plans in each region are mentioned. Responders from each region took part in a specially tailored “train the trainer” programme and then delivered training within their regions. A flexible approach to training within the HyResponder network has enabled fit for purpose region appropriate activities to be delivered impacting over 1250 individuals during the project and many more beyond. Teaching and learning materials in hydrogen safety for responders have been made available in 8 languages: English Czech Dutch French German Italian Norwegian Spanish. They are being used to inform training within each of the partner countries. Dedicated national working groups focused on hydrogen safety training for responders have been established in Belgium the Czech Republic Italy and Switzerland.

Proposals for achieving net-zero emissions by 2050 include scaling-up electrolytic hydrogen production however this poses technical economic and environmental challenges. One such challenge is for policymakers to ensure a sustainable future for the environment including freshwater and land resources while facilitating low-carbon hydrogen production using renewable wind and solar energy. We establish a country-by-country reference scenario for hydrogen demand in 2050 and compare it with land and water availability. Our analysis highlights countries that will be constrained by domestic natural resources to achieve electrolytic hydrogen self-sufficiency in a net-zero target. Depending on land allocation for the installation of solar panels or wind turbines less than 50% of hydrogen demand in 2050 could be met through a local production without land or water scarcity. Our findings identify potential importers and exporters of hydrogen or conversely exporters or importers of industries that would rely on electrolytic hydrogen. The abundance of land and water resources in Southern and Central-East Africa West Africa South America Canada and Australia make these countries potential leaders in hydrogen export.

Deploying renewable hydrogen presents a significant challenge in accessing off-takers who are willing to make long-term investments. To address this challenge current projects focus on large-scale deployment to replace the demand for non-renewable hydrogen particularly in ammonia synthesis for fertiliser production plants. The traditional process involving Steam Methane Reformers (SMR) connected to Haber-Bosch synthesis could potentially transition towards decarbonisation by gradually integrating water electrolysis. However the coexistence of these processes poses limitations in accommodating the integration of renewable hydrogen thereby creating operational challenges for industrial hubs. To tackle this issue this paper proposes an optimal dispatch model for producing green hydrogen and ammonia while considering the coexistence of different processes. Furthermore the objective is to analyse external factors that could determine the appropriate regulatory and pricing framework to facilitate the phase-out of SMR in favour of renewable hydrogen production. The paper presents a case study based in Spain utilising data from 2018 2022 and 2030 perspectives on the country's renewable resources gas and electricity wholesale markets pricing ranges and regulatory constraints to validate the model. The findings indicate that carbon emissions taxation and the availability and pricing of Power Purchase Agreements (PPAs) will play crucial roles in this transition - the carbon emission price required for total phasing out SMR with water electrolysis would be around 550 EUR/ton CO2.

Russia’s invasion of Ukraine has reaffirmed the importance of scaling up renewable energy to decarbonise Europe’s economy while rapidly reducing its exposure to foreign fossil fuel suppliers. Therefore the question of sources of flexibility to support a fully decarbonised European energy system is becoming even more critical in light of a renewable-dominated energy system. We developed and used a Pan-European energy system model to systematically assess and quantify sources of flexibility to meet deep decarbonisation targets. The electricity supply sector and electricity-based end-use technologies are crucial in achieving deep decarbonisation. Other low-carbon energy sources like biomethane hydrogen synthetic e-fuels and bioenergy with carbon capture and storage will also play a role. To support a fully decarbonised European energy system by 2050 both temporal and spatial flexibility will be needed. Spatial flexibility achieved through investments in national electricity networks and cross-border interconnections is crucial to support the aggressive roll-out of variable renewable energy sources. Cross-border trade in electricity is expected to increase and in deep decarbonisation scenarios the electricity transmission capacity will be larger than that of natural gas. Hydrogen storage and green hydrogen production will play a key role in providing traditional inter-seasonal flexibility and intraday flexibility will be provided by a combination of electrical energy storage hydrogen-based storage solutions (e.g. liquid H2 and pressurised storage) and hybrid heat pumps. Hydrogen networks and storage will become more critical as we move towards the highest decarbonisation scenario. Still the need for natural gas networks and storage will decrease substantially.

Proton exchange membrane (PEM) electrolyser stands as a promising candidate for sustainable hydrogen pro duction from renewable energy sources (RESs). Given the fluctuating nature of RESs accurate modelling of the PEM electrolyser is crucial. Nonetheless complex models of the PEM electrolyser demand substantial time and resource investments when integrating them into a large-scale power system. The majority of introduced models in the literature are either overly intricate or fail to effectively reproduce the dynamic behaviour of the PEM electrolyser. To this end this article aims to develop a model that not only captures the dynamic response of the PEM electrolyser crucial for conducting flexibility studies in the power system but also avoids complexity for seamless integration into large-scale simulations without comprising accuracy. To verify the model it is vali dated against static and dynamic experimental data. Compared to the investigated experimental cases the model exhibited an average error of 0.66% and 3.93% in the static and dynamic operation modes respectively.

The weather-dependent nature of renewable energy production has led to periodic overproduction making hydrogen production a practical solution for storing excess energy. In addition to conventional storage methods such as physical tanks or chemical bonding using the existing natural gas network as a storage medium has also proven to be effective. Households can play a role in this process as well. The purpose of these experiments is to evaluate the parameters of a household heating device currently in use but not initially designed for hydrogen operation. The appliance used in the tests has a closed combustion chamber with a natural draft induced by a density difference which is a common type. The tests were conducted at nominal load with a mix of 0–40 V/V% hydrogen and natural gas; no flashbacks or other issues occurred. As the hydrogen ratio increased from 0 to 40 V/V% the input heat decreased from 3.9 kW to 3.4 kW. The NOx concentration in the flue gas dropped from 26.2 ppm to 14.2 ppm and the CO2 content decreased from 4.5 V/V% to 3.4 V/V%. However the CO con centration slightly increased from 40.0 ppm to 44.1 ppm. Despite these changes efficiency remained stable fluctuating between 86.9% and 87.0%. The internal flame cone height was 3.27 mm when using natural gas but reduced sharply to just 0.38 mm when using 62 V/V% hydrogen. In addition to the fact that the article examines a group of devices that has been rarely investigated but is also widely distributed it also provides valuable experience for other experiments since the experiments were carried out with a higher hydrogen ratio compared to previous works.

This brochure provides a detailed overview of the EU’s funding mechanisms and an inspiring look at real projects managed by CINEA. These examples illustrate how diverse stakeholders from industry leaders to research institutions are translating hydrogen ambitions into impactful on-the-ground solutions that address both technological and societal needs.

This report aims to summarise the status of the European hydrogen market landscape. It is based on the information available at the European Hydrogen Observatory (EHO) initiative the leading source of data on hydrogen in Europe exploring the basic concepts latest trends and role of hydrogen in the energy transition. The data presented in this report is based on research conducted until the end of September 2024. This report contains information on current hydrogen production and trade distribution and storage end-use cost and technology manufacturing as of the end of 2023 except if stated otherwise in Europe. A substantial portion of the data gathering was carried out within the framework of Hydrogen Europe's efforts for the European Hydrogen Observatory. Downloadable spreadsheets of the data can be accessed on the website: https://observatory.clean-hydrogen.europa.eu/. The production and trade section provides insights into hydrogen production capacity and production output by technology in Europe and into international hydrogen trade (export and import) to and between European countries. The section referring to distribution and storage presents the location and main attributes of operational dedicated hydrogen pipelines and storage facilities as well as publicly accessible and operational hydrogen refuelling stations in Europe. The end-use section provides information on annual hydrogen consumption per end-use in Europe the deployment of hydrogen fuel cell electric vehicles in Europe the current and future hydrogen Valleys in Europe and the leading scenarios for future hydrogen demand in Europe in 2030 2040 and 2050 by sector. The cost chapter offers a comprehensive examination of the levelised cost of hydrogen production by technology and country. This chapter also gives estimations of renewable hydrogen break-even prices for different end-use applications in addition to electrolyser cost components by technology. Finally a chapter on technologies manufacturing explores data on the European electrolyser manufacturing capacity and sales and the fuel cell market.

This report aims to summarise the status of the European hydrogen policy landscape. It is based on the information available at the European Hydrogen Observatory (EHO) website the leading source of data on hydrogen in Europe. The data presented in this report is based on research conducted by Hydrogen Europe until the end of July 2024 but also goes beyond this timeline for major policies legislations or standards implemented recently. This report builds upon the previous version published in April 2024 which reflected data as of August 2023 providing updated insights on European policies and legislation national strategies national policies and legislation and codes and standards. Interactive data dashboards can be accessed on the website: https://observatory.cleanhydrogen.europa.eu/ The EU policies and legislation section provides insights into the main European policies and legislation relevant to the hydrogen sector which are briefly summarized on content and their potential impact to the sector. The national hydrogen strategies chapter offers a comprehensive examination of the hydrogen strategies adopted in Europe. It summarizes the quantitative indicators that have been published (targets and estimates) and provides brief summaries of the different national strategies that have been adopted. The section referring to national policies and legislation focuses on the policy framework measures incentives and targets in place that have an impact on the development of the respective national hydrogen markets within Europe. The codes and standards section provides information on current European standards and initiatives developed by the standardisation bodies including CEN CENELEC ISO IEC OIML The standards are categorised according to the different stages of the hydrogen value chain: production distribution and storage and end-use applications.

This report includes information on European training programmes educational materials and the trends and patterns of research and innovation activity in the hydrogen sector with data of patent registrations and publications. It is based on the information available at the European Hydrogen Observatory (EHO) website (https://observatory.cleanhydrogen.europa.eu/) the leading source of hydrogen data in Europe. The data presented in this report is based on research conducted until the end of August 2024. The training programmes section provides insights into major European training initiatives categorized by location. It allows filtering by type of training focus area and language. It covers a wide range of opportunities such as vocational and professional trainings summer schools and Bachelor's or Master's programmes. The education materials chapter summarizes the publicly accessible educational materials available online. Documents can be searched by educational level by course subject by language or by the year of release. The section referring to research and innovation activity analyses trends and patterns in the hydrogen sector using aggregated datasets of patent registrations and publications by country.

This report assesses the market readiness of zero-emission heavy-duty vehicles and the required infrastructure to meet the 45% emission reduction targets set by the revised CO2 standards by 2030. Achieving these goals requires the widespread adoption of zero-emission vehicles and a robust recharging and hydrogen refuelling infrastructure Three main aspects are investigated: the market readiness of the vehicles considering both the demand and supply side the corresponding infrastructure requirements and the barriers. Building on the inputs of the stakeholders a ‘study scenario’ is developed. This scenario shows a concrete picture of what the zero-emission heavy-duty vehicle fleet and its infrastructure requirement could look like by 2030. There are however key barriers that need to be overcome such as high total cost of ownership limited electricity grid capacity lengthy permitting processes and uncertainty in hydrogen availability and pricing. Stakeholders also emphasize the importance of policy drivers such as emissions trading systems and tolling and tax reforms to stimulate demand. In conclusion achieving the 2030 targets demands a coordinated approach involving manufacturers operators and policymakers to address infrastructure gaps market barriers and policy incentives ensuring the transition to a zero-emission HDV fleet.

Dual-fuel engines are a way of transitioning the marine sector to carbon-neutral fuels like hydrogen and methanol. For the development of these engines accurate simulation of the combustion process is needed for which calculating the pilot’s ignition delay is essential. The present work investigates novel methodologies for calculating this. This involves the use of chemical kinetic schemes to compute the ignition delay for various operating conditions. Machine learning techniques are used to train models on these data sets. A neural network model is then implemented in a dual-fuel combustion model to calculate the ignition delay time and is compared using a lookup table or a correlation. The numerical results are compared with experimental data from a dual-fuel medium-speed marine engine operating with hydrogen or methanol from which the method with best accuracy and fastest calculation is selected.