Local water supply crucial to success of hydrogen initiative in Europe

Chalmers University of Technology

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image: 

Map of a simulated risk of water stress in 2050 where hydrogen is used in transport and industry. Baseline risk (regardless of hydrogen use) is represented by the background color in each area. Dashed areas show water use exceeding available resources due to hydrogen production. Blue dots show areas where the risk of water stress increases by more than 50 percent in the simulation.

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Credit: Joel Löfving, Chalmers University of Technology

Green hydrogen is considered to be an important part of the global climate transition, especially as a fuel and energy carrier for heavy transport and industry. However, large-scale green hydrogen production requires sustainable ways of managing water resources to avoid giving rise to water shortages and conflicts with agriculture over access. This has been shown in a unique study from Chalmers University of Technology in Sweden, that connects local water supply with a range of scenarios for future hydrogen needs in Europe.

Replacing fossil fuels with hydrogen in the heavy-duty automotive and industrial sectors has the potential to greatly reduce emissions of the greenhouse gas carbon dioxide. This is especially true if the hydrogen gas is ‘green’, meaning that it is produced by electrolysis, a process whereby water is spit into hydrogen and oxygen using renewable electricity. A new study from Chalmers shows that planning where hydrogen will be manufactured, and the use of new technology solutions, is vital in order to avoid the large-scale production of green hydrogen leading to local water shortages in some parts of Europe.

In the study, published in Nature Sustainability, the researchers were able to explore different scenarios for how Europe’s hydrogen production might affect water resources, electricity prices and land use in 2050 – a year by which many countries have agreed to reduce their carbon emissions, which could mean the widespread use of hydrogen technology.

"Water is a resource that is often taken for granted in the energy transition. Our study is unique because we have connected the local perspective to the European perspective. We can show that even if hydrogen production does not require very much water in total compared to say agriculture, the local effects can be significant. This is because it’s better to produce hydrogen in close proximity to industry and access to renewable electricity, which generally means areas where water resources are already under strain. The conclusion is not that hydrogen production should be avoided, but that we must understand different perspectives and cooperate on many different levels – between government agencies, industry and local communities – to plan for the local effects of the transition,” says Joel Löfving, doctoral student at the Division of Transport, Energy and Environment at Chalmers.

Sörmland and Roslagen are high-risk areas

If hydrogen starts being widely used in industry and transport, the water supply might be severely impacted in multiple regions if the choice is to produce hydrogen locally, which is advantageous for economic reasons. For Sweden, it is anticipated that the water supply in the Sörmland and Roslagen regions, for example, is going to be hard pressed even without hydrogen production in 2050.  

“In Sörmland there is already a steel mill and a refinery. If they were to switch to hydrogen and use local water sources to produce it, this could exacerbate the projected water shortage. Also in the Roslagen region northeast of Stockholm, we can see that it might be difficult to source local water for the production of green hydrogen, and in the Bohuslän region on the Swedish west coast, and parts of Norrland in the north, large-scale hydrogen production could increase water withdrawal by more than 50 per cent. Although the water supply there is considered to be good, there is a risk that this production could have a significant impact on the natural environment” he says.

The study analysed over 700 local water sub-basins in Europe, and similar patterns to those seen in Sweden could be identified in multiple locations. In southern and central Europe, where favourable conditions for generating electricity with solar and wind power make green hydrogen production particularly attractive, access to water is estimated to be very limited by 2050, as local water resources are already under strain and vulnerable to climate change. Major industry clusters in Spain, Germany, France and the Netherlands, for example, could thus face a conflict with agriculture, for example, over water resources.

“There are many potential conflicts around water as a resource, but also many solutions, such as seawater desalination or the reuse of water from wastewater treatment plants. There are also interesting synergies, as the oxygen that remains from the hydrogen production could be used in the processes that treat the wastewater. Hydrogen has great potential to contribute to the climate transition, but we need to find sustainable ways to manage water resources – for the production of fuel and for agriculture,” says Joel Löfving.

Electricity prices impacted less than expected

In addition to water use, the researchers studied how a large-scale hydrogen economy could affect Europe’s electricity prices. By plugging the hydrogen model into Chalmers’ Multinode model – a model developed for optimising the costs of Europe’s energy system in different scenarios – they were able to estimate changes in electricity prices between different regions.

The results show that electricity demand increases significantly in line with the amount of hydrogen produced, since it takes a lot of electricity to replace the energy in the fossil fuels that so far we have simply taken out of the ground. Despite this, the results show that the impact on average electricity prices in Europe is relatively small. In regions with good access to renewable energy sources, such as northern Europe, the price impact is the smallest. In southern Europe, where some regions are dependent on a higher proportion of electricity from gas or nuclear power, for example, bigger price increases were seen.

“Electricity prices are a sensitive issue, but our modeling shows that increased investment in electricity production for producing hydrogen does not necessarily lead to higher prices for consumers. This is an important message to decision-makers – to cope with the energy transition, all fossil-free energy sources are needed and we must have the courage to invest in new, green electricity production,” says Joel Löfving.

Broad patterns and local consequences

Large-scale green hydrogen production would require a big expansion of solar and wind power. But the expansion would only take up a few per cent of the land currently used for agriculture, according to the study. And this area is significantly less than would be required to replace the same amount of energy with biofuels.

The researchers argue that, taken together, the results provide an important holistic perspective on Europe’s energy transition. Previous studies have often focused on either local effects or effects at overarching system levels, but rarely combined both.

“It was this connection that we wanted to make. If we are going to build the future’s energy system, we need to understand both the broad patterns and the local consequences. By considering risks, we will be able to manage them, and thus create more certainty for investments in green technology,” says Joel Löfving.

 

 

 

Green hydrogen

Produced by electrolysis when water is split into hydrogen and oxygen using electricity. The electricity used must come from renewable sources such as solar, wind or hydro power for the hydrogen to be labelled ‘green’.

 

More about the research:

The study “Resource requirements and consequences of large-scale hydrogen use in Europe” has been published in Nature Sustainability. The authors are Joel Löfving, Selma Brynolf, Maria Grahn, Simon Öberg and Maria Taljegard, all working at Chalmers University of Technology. The research was carried out within the competence centre TechForH2 and the Division of Transport, Energy and Environment in collaboration with the Division of Energy Technology.

 

For more information, please contact:

Joel Löfving, doctoral student at the Division of Transport, Energy and Environment, Chalmers University of Technology: +46 31 772 16 47, joel.lofving@chalmers.se

Maria Grahn, Associate Professor at the Division of Transport, Energy and Environment, Chalmers University of Technology: +46 31 772 31 04, maria.grahn@chalmers.se

 

Caption: Map of a simulated risk of water stress in 2050 where hydrogen is used in transport and industry. Baseline risk (regardless of hydrogen use) is represented by the background color in each area. Dashed areas show water use exceeding available resources due to hydrogen production. Blue dots show areas where the risk of water stress increases by more than 50 percent in the simulation. Illustration: Joel Löfving, Chalmers University of Technology

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Journal

Nature Sustainability

DOI

10.1038/s41893-026-01771-5 

Method of Research

Computational simulation/modeling

Subject of Research

Not applicable

Article Title

Resource requirements and consequences of large-scale hydrogen use in Europe

 

Water: the unlikely hero in creating next-generation green hydrophobic materials for environmental cleanup

Researchers pioneer a mechanochemical approach using water as a green initiator to transform renewable resources into high-performance porous materials capable of capturing CO₂ while removing pollutants

Journal of Bioresources and Bioproducts

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Researchers pioneer a mechanochemical approach using water as a green initiator to transform renewable resources into high-performance porous materials capable of capturing CO₂ while removing pollutants

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Credit: Hebei Key Laboratory of Close-to-Nature Restoration Technology of Wetlands, School of Eco-Environment, Hebei University, Baoding 071002, China

Traditional approaches to synthesizing hydrophobic materials have long been plagued by inherent limitations, typically relying on energy-intensive high-temperature processes, environmentally harmful organic solvents, and expensive coupling agents that generate toxic byproducts. Now, a paradigm-shifting study published in the Journal of Bioresources and Bioproducts demonstrates that the most abundant substance on Earth—water—can serve as a powerful catalyst for creating advanced functional materials from renewable resources.
The breakthrough lies in the elegant simplicity of mechanochemical activation. By employing a ball milling process with trace amounts of water, researchers successfully activated sodium methylsilicate to generate highly reactive hydroxyl groups, which subsequently undergo condensation reactions with diverse substrates to form robust three-dimensional network structures with inherent porosity and exceptional hydrophobic characteristics. What distinguishes this methodology is its remarkable substrate versatility: the system accommodates over 40 different materials through distinct connection strategies, including small molecules, linear polymers like cellulose, planar polymers such as lignin, and even untreated plant tissues where intrinsic water content initiates the reaction without additional processing.
The environmental credentials extend beyond solvent elimination. The reaction mechanism inherently captures atmospheric carbon dioxide, converting it into sodium bicarbonate as a valuable byproduct—transforming material synthesis from a carbon-intensive process into a carbon-negative operation. Performance characterization reveals materials with surface areas of 129–388 m2/g and superhydrophobic behavior with contact angles exceeding 150°.
Practical applications validate the technological potential across diverse sectors. In oil-water separation, reed-derived materials achieved petroleum ether permeability exceeding 801 L/(m2·h) under gravity-driven conditions. For pharmaceutical waste management, lignin-based materials demonstrated 85% removal efficiency for propofol. The materials also exhibited exceptional catalytic degradation capabilities, achieving 90–99.99% removal rates for industrial dyes. Significantly, the methodology demonstrates genuine scalability, with successful production at the decagram scale while maintaining consistent structural properties—positioning the technology for practical industrial implementation.

 

See the article:

DOI

https://doi.org/10.1016/j.jobab.2026.100247

Original Source URL

https://www.sciencedirect.com/science/article/pii/S2369969826000198

Journal

Journal of Bioresources and Bioproducts

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Journal

Journal of Bioresources and Bioproducts

DOI

10.1016/j.jobab.2026.100247 

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

H2O As an Efficient Green Initiator to Construct Renewable Hydrophobic Porous Materials for Pollutant Removal

 

One‑eyed creature gave rise to our modern eyes

“It’s mind‑boggling that our pineal gland’s ability to regulate our sleep according to light stems from the cyclopean median eye of a distant ancestor 600 million years ago,”

Lund University

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There is a tiny cyclops among your oldest ancestors, and humans share these remarkable ancestral roots with all other vertebrates. This according to new, surprising research on the evolution of the eye.

Researchers from Lund University and the University of Sussex have found that all vertebrates evolved from a distant ancestor that had a single eye located at the top of its head. The study also reveals that the remnants of this so‑called median eye have today become the pineal gland in our brains.

“The results are a surprise. They turn our understanding of the evolution of the eye and the brain upside down,” says Dan‑E Nilsson, professor emeritus in sensory biology at Lund University.

This cyclops‑like creature, which is our very distant relative, existed almost 600 million years ago. It was a small, worm‑like organism that had adopted a sedentary lifestyle and fed by filtering plankton from seawater. Previously, this creature had some form of paired eyes, like most other animals.

“We don’t know whether the paired eyes in our branch of the evolutionary tree were just light‑sensitive cells or simple image‑forming eyes. We only know that the organism later lost them,” says Dan‑E Nilsson.

The increasingly calm lifestyle meant that the worm‑like creature no longer needed paired eyes, and therefore that function was lost over the course of evolution. However, the animal kept a group of light‑sensitive cells in the middle of its head. These cells developed into a small, primitive median eye that could keep track of night and day, and sense what was up and down.

Over the following millions of years, our distant ancestor once again began to live an active, swimming life, increasing the need for paired eyes. From parts of the small median eye, new image‑forming eyes in pairs developed, the researchers conclude in the study.

“Now we finally understand why the eyes of vertebrates differ so radically from the eyes of all other animal groups, such as insects and squid. The film of our eyes - the retina - developed from the brain, whereas the eyes of insects and squid originate in the skin on the sides of the head,” says Dan‑E Nilsson.

In other words, vertebrate eyes constitute a more modern model that evolved thanks to this peculiar detour via a cyclops’ sedentary life. The conclusion that our modern eyes evolved through this specific evolutionary path, and not via some other ancient animal, is based on the researchers’ extensive analysis of light‑sensitive cells in all animal groups, as well as the physiology and placement of these cells in the body.

“For the first time, we now also understand the origin of the neural circuits that analyse the image in our retina,” adds Dan‑E Nilsson.

A fascinating fact is that remnants of the ancient median eye from our distant ancestor actually remain in our heads today, transformed into the pineal gland. The pineal gland is a light‑sensitive organ in the vertebrate brain. It produces the hormone melatonin, which helps regulate the body’s circadian rhythm.

“It’s mind‑boggling that our pineal gland’s ability to regulate our sleep according to light stems from the cyclopean median eye of a distant ancestor 600 million years ago,” concludes Dan‑E Nilsson.

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Journal

Current Biology

DOI

10.1016/j.cub.2025.12.028 

Article Title

Evolution of the vertebrate retina by repurposing of a composite ancestral median eye

 

Citizens engage with information in different ways during a crisis – understanding this can support public authorities’ communication efforts

University of Eastern Finland

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The COVID-19 pandemic was a major health crisis that challenged citizens’ information management routines. Epistemic ideals guided how people scanned and filtered information, engaged with it and adapted their behaviour accordingly.

Conducted in Finland, a recent study found that four distinctive profiles characterise citizens’ engagement with information. 

Those emphasising the accuracy of information considered it essential that information was precise and scientifically valid. They considered it important to defend what they perceived as correct information, particularly against mis- or disinformation.

Those emphasising the plausibility of information interpreted meaningful information based on who was presenting it. For instance, people in this group believed that the most reliable information on the effects of COVID-19 restrictions came from people who had personally experienced those effects. They sought and interpreted information with others who shared similar backgrounds, and they actively disseminated it within society.

Those emphasising the credibility of information assessed information as part of a broader ideological framework. Information they perceived as correct did not conflict with their own values. They gathered information through a very narrow lens, but felt little need to share their own interpretations with others.

Those emphasising the cohesion of information considered it important that information did not create or increase societal tensions. For them, the most valid information was that which was broadly accepted. They interpreted changing situations in ways that avoided conflict and were widely endorsed.

Collaboration between citizens and public authorities is strengthened by authorities’ ability to take different ways of engaging with information into account in their activities and communication in times of crisis. This is particularly important during periods when uncertainty and rapid changes highlight the importance of collaboration.

“When public authorities are aware of the different ways in which citizens engage with information, they can adjust their communication and leadership to ensure that as many citizens as possible can find valid and appropriate information in a way that suits them,” says Marilla Kortesalmi, University Lecturer in Home Economics at the University of Eastern Finland.

The existence of various epistemic ideals was made visible by the pandemic, but Kortesalmi notes that we constantly employ epistemic ideals when assessing important and meaningful information.

“Understanding this may lead to, for example, fewer anti-vaccination views, adoption of protective behaviours or compliance with public guidelines.”

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Journal

International Journal of Public Sector Management

DOI

10.1108/IJPSM-06-2025-0263 

Article Title

Citizen engagement with information when adapting to health crises: four distinctive profiles