Publications

This article explores how the implementation of solar PV and transportation infrastructure – grid or hydrogen pipeline – has implications for various aspects of security cooperation and geopolitical powershifts. Highlighting the emerging intra-European green hydrogen pipeline project H2Med we examine the Portuguese geopolitical ambitions related to their geographical advantage for solar PV energy production. Using media and document analysis we identified two main axes of solar PV implementation in Portugal – one centered on resilience and one on exports – and further explored underlying and resulting tensions in neighboring countries’ energy strategies and cleantech innovation policies. Our analysis revealed that policy prioritizations in solar PV diffusion result in unequal effects on resilience energy security and power shifts. In particular solar PV implementations such as individual to local or regional grid-based ‘prosumption’ setups result in notably different geopolitical effects compared to large-scale solar PV to green hydrogen-production for storage and export. Thereby emerging possibilities of storage and long-distance trade of renewable energies have more significant implications on geopolitics and energy security than what is typically recognized.

The growing demand for sustainable solutions in the transportation sector and global decarbonization goals have fueled debate on using hydrogen as an energy source. Although hydrogen’s potential is recognized in Brazil its application in heavy-duty vehicles still faces structural and technological barriers. This study aimed to analyze the viability of hydrogen as an energy alternative for trucks in Brazil. The research adopted an exploratory qualitative approach based on the expert analysis method through semi-structured interviews with development engineers representatives of heavy-duty vehicle manufacturers and researchers specializing in hydrogen technologies. The data were organized into a thematic framework and interpreted using content analysis. The results show that although there is growing interest and ongoing initiatives challenges such as the cost of fuel cells the lack of refueling infrastructure and low technological maturity hinder large-scale adoption. From a theoretical perspective the study contributes by integrating specialized literature with practical insights from key industry players broadening the understanding of the energy transition. In practical terms it outlines some strategic paths such as expanding technological development and forming partnerships. From a social perspective it emphasizes the importance of hydrogen as a pillar for sustainable low-carbon mobility capable of positively impacting public health and mitigating climate change.

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.

Green hydrogen produced from renewable energy sources such as wind and solar is increasingly recognized as a critical enabler of the global energy transition and the decarbonization of industrial and transport sectors. The successful adoption of green hydrogen and its derivatives is closely linked to production costs which can vary substantially between countries depending not only on resource potential but also on country-specific financing conditions. These differences arise from country-specific risk factors that affect the costs of capital ultimately influencing investment decisions. However comprehensive assessments that integrate these risks with future cost projections for renewable energy green hydrogen and its synthetic downstream products are lacking. Using the Middle East and North Africa (MENA) as an example this study introduces a novel approach that allows to incorporate mainly qualitative country-specific investment risks into quantitative analyses such as costpotential and energy modelling. Our methodology calculates weighted average costs of capital (WACC) for 17 MENA countries under different risk scenarios providing a more nuanced assessment compared to traditional models that use uniform cost of capital assumptions. The results indicate significant variations in WACC such as between 4.67% in the United Arab Emirates and 24.84% in Yemen or Syria in the business-as-usual scenario. The incorporation of country-specific capital cost scenarios in quantitative analysis is demonstrated by modelling the cost-potential of Fischer-Tropsch (FT) fuels. The results show that countryspecific investment risks significantly impact costs. For instance by 2050 the starting LCOFs in high-risk scenarios can be up to 180% higher than in lowerrisk contexts. This underlines that while renewable energy potential and its cost are important it are the country-specific risk factors—captured through WACC—that have a greater influence in determining the competitiveness of exports and consequently the overall development of the renewable energy green hydrogen and synthetic fuel sectors.

Green hydrogen is increasingly recognized as a pivotal energy carrier in the global transition toward low-carbon energy systems. Beyond its established applications in industry and transportation the development of green hydrogen could accelerate its integration into the power generation sector thus enabling a more sustainable deployment of renewable energy sources. Vietnam endowed with abundant renewable energy potential—particularly solar and wind—has a strong foundation for green hydrogen. This emerging energy source holds significant potential to support the strategic objectives in recent national energy policies aligning with the country’s socio-economic development. However despite this promise the integration of green hydrogen into Vietnam’s energy system remains limited. This paper provides a critical review of the current landscape of green hydrogen in Vietnam examining both the opportunities and challenges associated with its production and deployment. Special attention is given to regulatory frameworks infrastructure readiness and economic viability. Additionally the study also explores the potential of green hydrogen in enhancing energy security within the context of the national energy transition.

Photocatalytic hydrogen (H2) production offers a promising solution to energy shortages and environmental challenges by converting solar energy into chemical energy. Hydrogen as a versatile energy carrier can be generated through photocatalysis under sunlight or via electrolysis powered by solar or wind energy. However the advancement of photocatalysis is hindered by the limited availability of effective visible light-responsive semiconductors and the challenges of charge separation and transport. To address these issues researchers are focusing on the development of novel nanostructured semiconductors and composite materials that can enhance photocatalytic performance. In this paper we provide an overview of the advanced photocatalytic materials prepared so far that can be activated by sunlight and their efficiency in H2 production. One of the key strategies in this research area concerns improving the separation and transfer of electron–hole pairs generated by light which can significantly boost H2 production. Advanced hybrid materials such as organic–inorganic hybrid composites consisting of a combination of polymers with metal oxide photocatalysts and the creation of heterojunctions are seen as effective methods to improve charge separation and interfacial interactions. The development of Schottky heterojunctions Z-type heterojunctions p–n heterojunctions from nanostructures and the incorporation of nonmetallic atoms have proven to reduce photocorrosion and enhance photocatalytic efficiency. Despite these advancements designing efficient semiconductor-based heterojunctions at the atomic scale remains a significant challenge for the realization of large-scale photocatalytic H2 production. In this review state-of-the-art advancements in photocatalytic hydrogen production are presented and discussed in detail with a focus on photocatalytic nanostructures heterojunctions and hybrid composites.

The potential for hydrogen to reshape energy systems has been recognized for over a century. Yet as decarbonization priorities have sharpened in many regions three distinct frontier areas are critical to consider: hydrogen produced from wind; hydrogen produced from nuclear power; and the development of natural hydrogen. These pathways reflect technology and policy changes including a 54% increase in the globally installed wind capacity since 2020 plus new signs of potential emerging in nuclear energy and natural hydrogen. Broadly speaking there are a considerable number of studies covering hydrogen production from electrolysis yet none systematically examine wind- and nuclear-derived hydrogen natural hydrogen or the policies that enable their adoption in key countries. This article highlights international policy and technology developments with a focus on prime movers: Germany China the US and Russia.

Underground hydrogen storage (UHS) in geological formations presents a viable option for long-term large-scale H2 storage. A physical coal model was constructed based on experimental tests and a MD simulation was used to investigate the potential of UHS in underground coal gasification (UCG) cavities. We investigated H2 behavior under various conditions including temperatures ranging from 278.15 to 348.15 K pressures in the range of 5–20 MPa pore sizes ranging from 1 to 20 nm and varying water content. We also examined the competitive adsorption dynamics of H2 in the presence of CH4 and CO2 . The findings indicate that the optimal UHS conditions for pure H2 involve low temperatures and high pressures. We found that coal nanopores larger than 7.5 nm optimize H2 diffusion. Additionally higher water content creates barriers to hydrogen diffusion due to water molecule clusters on coal surfaces. The preferential adsorption of CO2 and CH4 over H2 reduces H2 -coal interactions. This work provides a significant understanding of the microscopic behaviors of hydrogen in coal nanopores at UCG cavity boundaries under various environmental factors. It also confirms the feasibility of underground hydrogen storage (UHS) in UCG cavities.

Natural hydrogen or "white hydrogen" has recently garnered attention as a viable and cost-effective energy resource due to its low-carbon footprint and high energy density positioning it as a key contributor to the transition towards a sustainable low-carbon energy system. This study represents Alberta’s first systematic effort to evaluate natural hydrogen potential in the province using publicly available geological geospatial and gas composition datasets. By mapping hydrogen occurrences against key geological features in the Western Canadian Sedimentary Basin (WCSB) we identify regions with strong geological potential for natural hydrogen generation migration and accumulation while addressing data uncertainties. Within the WCSB formations like the Montney Cardium Bearpaw Manville Belly River McMurray and Lea Park are identified as zones likely for hydrogen generation by prominent mechanisms including hydrocarbon decomposition water-rock reactions with iron-rich sediments and organic pyrolysis. Formation proximity to the underlying Canadian Shield may also suggest potential for basement-derived hydrogen migration via deep-seated faults and shear zones. Salt deposits (Elk Point Group - Prairie evaporites Cold Lake and Lotsberg) and deep shales (e.g. Kaskapau Lea Park Wapiabi) provide effective cap rock potential while reservoirs like porous sandstone (e.g. Dunvegan Spirit River Cardium) and fractured carbonate (e.g. Keg River) formations offer favorable accumulation conditions. Hydrogen occurrences in relation to geological features identify Southern Eastern and West-Central plains as prominent natural Hydrogen generation and accumulation areas. Alberta’s established energy infrastructure as well as subsurface expertise positions it as a potential leader in natural hydrogen exploration. As Alberta’s first systematic investigation this study provides a preliminary assessment of natural hydrogen potential and outlines recommended next steps to guide future exploration and research. Targeted research on specific generation and accumulation mechanisms and source identification through isotopic and geochemical fingerprinting will be crucial for exploration de-risking and viability assessment in support of net-zero emission initiatives.

Introduction: With the increasing demand for energy utilization efficiency and minimization of environmental carbon emissions in industrial parks optimizing the configuration and scheduling of integrated energy systems has become crucial. This study focuses on integrated energy systems with massive flexible load resources aiming to maximize energy utilization efficiency while reducing environmental impact. Methods: To model the uncertainties in wind and solar power outputs we employed three-parameter Weibull distribution models and Beta distribution models. Flexible loads were categorized into three types to match different electricity consumption patterns. Additionally an enhanced Kepler Optimization Algorithm (EKOA) was proposed incorporating chaos mapping and adaptive learning rate strategies to improve search scope convergence speed and solution efficiency. The effectiveness of the proposed optimization scheduling and configuration methods was validated through a case study of an industrial park located in a coastal area of southeastern China. Results: The results show that using three-parameter Weibull distribution models and Beta distribution models more accurately reflects the variations in actual wind speeds and solar irradiance levels achieving peak shaving and valley filling effects and enhancing renewable energy utilization. The EKOA algorithm significantly reduced curtailment rates of wind and solar power generation while achieving substantial economic benefits. Compared with other operation modes of hydrogen the daily average cost is reduced by 12.92% and external electricity purchases are reduced by an average of 20.2 MW h/day. Discussion: Although our approach shows potential in improving energy utilization efficiency and economic gains this paper only considered hydrogen energy for single-use pathways and did not account for the economic benefits from selling hydrogen in the market. Future research will further incorporate hydrogen demand response mechanisms and optimize the output of integrated energy systems from the perspective of spot markets. These findings provide valuable references for relevant engineering applications.