Wednesday, July 30, 2025

A more climate-friendly way to produce nitrogen fertilizer

Nikolay Kornienko’s team shows how ammonia can be produced from water and nitrogen gas using electricity from solar and wind

University of Bonn

Reactor schematic — image:
in which water is directly used as a hydrogen source to generate ammonia via electric power.
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Credit: Image: Nikolay Kornienko

Humanity has an insatiable appetite for ammonia: this substance is used to make fertilizer, which in turn is used in most modern agriculture. Until now, the Haber-Bosch process has been the method of choice for extracting nitrogen from the seemingly inexhaustible atmosphere and binding it in the form of ammonia. However, this method requires an extremely large amount of methane gas and energy. Prof. Nikolay Kornienko from the University of Bonn has discovered a more climate-friendly alternative for producing ammonia from renewable energy sources. The research team is now presenting its findings in the journal Nature Communications.

Like in the Garden of Eden: Grain, beets, and potatoes should sprout as luxuriantly as possible so that plates are well filled. This is ensured by regular fertilization—especially with nitrogen. A source of nutrients that seems to never run dry. At the beginning of the 20th century, Fritz Haber and Carl Bosch developed a process that extracts nitrogen from the seemingly inexhaustible air. This achievement earned them the Nobel Prize in Chemistry in 1918.

Using an iron-based catalyst, very high pressure, and temperatures of up to 500 degrees Celsius, the Haber-Bosch process binds nitrogen from the air to hydrogen, producing ammonia. As an aside, some plants also master the art of binding atmospheric nitrogen with tiny bacteria in their roots and making it available for their growth. However, green plants do this in a climate-neutral way, whereas humans have not yet managed to do so.

“The Haber-Bosch process is extremely energy-intensive,” says Prof. Dr. Nikolay Kornienko from the Institute of Inorganic Chemistry at the University of Bonn. Ammonia production is based predominantly on fossil fuels, which means that greenhouse gas emissions are correspondingly high. “In order to achieve the goal of a sustainable and climate-neutral society, the search for alternative ammonia synthesis processes is a priority,” says Kornienko, who is also a member of the transdisciplinary research area “Matter” at the University of Bonn.

Nitrogen fertilizer from sun and wind

Alternative methods? These have been experimented with for some time. The aim is to replace the Haber-Bosch ammonia synthesis with a process that uses renewable energy from sources such as the sun and wind. The hydrogen required would then no longer come from methane gas, but would be obtained directly from the electrical splitting of water (H2O) into hydrogen (H2) and oxygen (O2). Sounds simple? It's not. Anyone who wants to produce ammonia on a large scale using wind and solar power has to navigate a number of pitfalls in the chemical reaction pathways.

“The lithium-mediated nitrogen reduction reaction (LiNRR) is considered the most robust way to electrify ammonia synthesis,” says Hossein Bemana, the lead author of the study. In this system, lithium ions (Li+) are electrochemically reduced to a lithium metal layer. This lithium metal can then react with nitrogen gas (N2) to form a lithium-nitrogen compound. If a hydrogen source is available, the lithium-nitrogen compound is converted into ammonia (NH3) and dissolved lithium ions. Then the process starts all over again. That's the theory, at least.

“We generally view this system as a model for the time being, as there are several practical difficulties,” says Kornienko. Because high voltage is required to reduce lithium ions to metallic lithium, energy efficiency is limited to around 25 percent. In addition, the system must operate in an air- and water-free environment, as lithium metal is highly reactive. Another challenge is that, similar to batteries, a porous solid electrolyte interphase (SEI) grows on the lithium layer. This layer must allow nitrogen gas and hydrogen to pass through as reactants to the lithium.

The wrong thing is sacrificed

Ideally, the hydrogen would come directly from the splitting of water. However, in this system, alcohols are usually used as the hydrogen source. In some cases, the solvent also decomposes and then serves as a hydrogen source itself. “This makes the system impractical, as several alcohol or solvent molecules have to be sacrificed to produce ammonium,” says the chemist.

However, the researchers have found a way to extract hydrogen directly from the splitting of water and transfer it to nitrogen. They used a palladium (Pd) foil as both an electrode and a membrane. “Palladium can serve as a membrane because it allows hydrogen atoms to pass through,” reports Kornienko. In the experiment, the Pd foil separated an anhydrous reaction environment, in which the LiNRR reactions take place, from a water-based reaction environment. “In the end, we were able to extract hydrogen atoms electrochemically directly from the water and transfer them to the reactive lithium/lithium-nitrogen material to produce ammonia,” says the chemist.

The researchers used infrared spectroscopy and mass spectrometry to verify that this really works as intended. They used a heavy isotope of hydrogen (deuterium = D) as a water source and produced ND3 instead of NH3. Conversely, the researchers labeled all molecules in the LiNRR compartment with D instead of H – as desired, NH3 was produced in this case and not ND3 as before.

Researchers file patent application

Hossein Bemana and Nikolay Kornienko have already filed a patent application for this process. The research team used only electricity for its experiments to produce ammonia (NH3). However, there is still a long way to go before the desired nitrogen fertilizer can be produced economically from renewable energy sources. To achieve this, scientists would have to achieve a yield 1,000 times greater than in their current experiments. “We are still in the early stages,” says the chemist. “In general, research needs to be done on the reaction rates and selectivity of the system—the control of electrons to the desired target.”

Funding:

The German Research Foundation (DFG) funded the project. The Open Access Publication Fund of the University of Bonn supported the publication.

Publication: Hossein Bemana, Hendrik Schumann, Morgan McKee, Senada Nozinovic, Jörg Daniels, Ralf Weisbarth, Nikolay Kornienko: Accelerating lithium-mediated nitrogen reduction through an integrated palladium membrane hydrogenation reactor, “Nature Communications,” DOI: 10.1038/s41467-025-62088-z, URL: https://www.nature.com/articles/s41467-025-62088-z

Journal

Nature Communications

DOI

10.1038/s41467-025-62088-z

Method of Research

Experimental study

Subject of Research

Not applicable

Article Title

Accelerating lithium-mediated nitrogen reduction through an integrated palladium membrane hydrogenation reactor

Article Publication Date

28-Jul-2025

Bridges that talk: GNSS reveals hidden structural shifts

Aerospace Information Research Institute, Chinese Academy of Sciences

image:
Relation among BCS, n-frame, and b-frame.
view more
Credit: Satellite Navigation

Bridges endure constant environmental and operational stresses—some visible, others imperceptible. This study introduces an innovative Global Navigation Satellite System (GNSS)-based system that simultaneously tracks both displacement and structural attitude, such as pitch and heading. Unlike traditional systems that only measure movement, this integrated approach provides a more complete picture of how bridges respond to real-world forces like wind and temperature shifts. Through real-time, high-precision data collection and analysis, the method enables earlier detection of structural anomalies, paving the way for safer and smarter infrastructure management.

Long-span bridges are engineering marvels—but they also face constant challenges from wind, traffic, and thermal expansion. Monitoring these dynamic responses has long relied on displacement data alone, often missing subtle changes in orientation that precede more visible damage. Emerging technologies such as Global Navigation Satellite System (GNSS) have enhanced position tracking, but integrating attitude determination—particularly in real time—remains difficult. Existing methods either separate displacement and attitude estimation or lack the precision needed for early warnings. Due to these challenges, there is a critical need to develop integrated systems that can monitor both displacement and attitude for a fuller understanding of structural behavior.

A research team led by Southeast University has developed a cutting-edge GNSS-based method to monitor both displacement and attitude of long-span bridges with remarkable accuracy. Published (DOI: 10.1186/s43020-025-00174-9) in Satellite Navigation in July 2025, the study evaluates the system on the Forth Road Bridge in Scotland. The approach combines data from multiple GNSS antennas and employs the Unscented Kalman Filter (UKF) to track real-time structural changes under varying environmental conditions, including strong winds and temperature shifts.

This new method, termed Integrated Displacement and Attitude Determination (IDAD), uses GNSS data from multiple antennas placed along the bridge to capture both movement and orientation. Unlike traditional two-step methods, IDAD uses a unified model powered by UKF, allowing it to resolve GNSS ambiguities and fuse displacement and attitude data in real time. The system achieved sub-centimeter displacement accuracy (0.004–0.006 m horizontally, 0.008–0.010 m vertically) and micro-degree attitude precision (pitch 0.0013°, heading 0.0004°) using baselines as long as 2 km. Field testing during winter storms showed the system's ability to detect heading and pitch variations in response to lateral wind forces and temperature changes. These small yet meaningful shifts provide early signs of structural strain that might otherwise go unnoticed. Importantly, the IDAD approach preserves the cross-correlation between displacement and attitude, offering a new lens to interpret bridge health dynamics holistically.

“By integrating displacement and attitude into one estimation framework, we're capturing a dimension of structural behavior that has been largely overlooked,” says Professor Xiaolin Meng, senior author of the study. “This level of insight allows us to better understand how bridges breathe and bend—vital knowledge for proactive maintenance and public safety.”

This integrated GNSS approach signals a new era in structural health monitoring. Beyond bridges, it could be adapted for skyscrapers, dams, and offshore platforms—anywhere subtle shifts can accumulate into serious risks. Its ability to deliver accurate, real-time data without relying on inertial sensors also simplifies deployment and lowers cost. Most critically, the method lays the foundation for future systems combining GNSS with IMUs in tightly coupled configurations for structural health monitoring, potentially enabling high-frequency monitoring in challenging environments. With infrastructure aging globally, the adoption of such multidimensional monitoring systems may be key to building safer, smarter cities.

###

References

DOI

10.1186/s43020-025-00174-9

Original Source URL

https://doi.org/10.1186/s43020-025-00174-9

Funding information

This research is funded by the project “BeiDou/GNSS Multi-Sourced Data Fusion Theory and Digital Twinning Method for Real-Time and Condition Diagnosis of Large-Span Bridges” from the National Natural Science Foundation of China (No. 42430711), and supported by “the Fundamental Research Funds for the Central Universities” (No. 2242025K20010).

About Satellite Navigation

Satellite Navigation (E-ISSN: 2662-1363; ISSN: 2662-9291) is the official journal of Aerospace Information Research Institute, Chinese Academy of Sciences. The journal aims to report innovative ideas, new results or progress on the theoretical techniques and applications of satellite navigation. The journal welcomes original articles, reviews and commentaries.

Journal

Satellite Navigation

DOI

10.1186/s43020-025-00174-9

Subject of Research

Not applicable

Article Title

GNSS integrated displacement and attitude determination for structural health monitoring of long-span bridges

Article Publication Date

15-Jul-2025

Stronger, cheaper titanium a ‘leap forward’ for industry

Engineers from RMIT University have produced a new type of 3D-printed titanium that’s about a third cheaper than commonly used titanium alloys

RMIT University

image:
PhD candidate and study lead author Ryan Brooke inspects a sample of the new titanium.
view more
Credit: Michael Quin, RMIT University.

Engineers from RMIT University, Australia, have produced a new type of 3D-printed titanium that’s about a third cheaper than commonly used titanium alloys. 

The team used readily available and cheaper alternative materials to replace the increasingly expensive vanadium.

RMIT has filed a provisional patent on their innovative approach, which has also been outlined in Nature Communications, as the team considers commercial opportunities to develop the new low-cost approach for aerospace and medical device industries.

RMIT’s Centre for Additive Manufacturing (RCAM) PhD candidate and study lead author Ryan Brooke said testing of their alloy showed improved strength and performance compared to standard 3D-printed titanium alloys (Ti-6Al-4V). 

Brooke, who has just accepted a Research Translation Fellowship at RMIT to investigate the next steps of commercialising the technology, said the area of 3D-printed titanium alloys was ripe for innovations. 

“3D printing allows faster, less wasteful and more tailorable production yet we’re still relying on legacy alloys like Ti-6Al-4V that doesn’t allow full capitalisation of this potential. It’s like we’ve created an aeroplane and are still just driving it around the streets,” he said.

“New types of titanium and other alloys will allow us to really push the boundaries of what’s possible with 3D printing and the framework for designing new alloys outlined in our study is a significant step in that direction.”  

The latest study outlines a time- and cost-saving method to select elements for alloying, to take advantage of emerging 3D-printing technology.

This work provides a clearer framework for predicting the printed grain structure of metallic alloys in additive manufacturing. 

It has already been used to achieve impressive results: the team’s alloy, while not presented in the study for commercial reasons, is 29% cheaper to produce than standard titanium.

Through this design framework, the metal also prints more evenly, avoiding the column-shaped microstructures that lead to uneven mechanical properties in some 3D printed alloys. 

“By developing a more cost-effective formula that avoids this columnar microstructure, we have solved two key challenges preventing widespread adoption of 3D printing,” said Brooke, who recently completed market validation as part of CSIRO’s ON Prime program talking to aerospace, automotive and MedTech industry representatives about their needs. 

“What I heard loud and clear from end users was that to bring new alloys to market, the benefits have to not just be minor incremental steps but a full leap forward, and that’s what we have achieved here,” he said.

“We have been able to not only produce titanium alloys with a uniform grain structure, but with reduced costs, while also making it stronger and more ductile.” 

Study corresponding author Professor Mark Easton said RCAM was focused on creating new collaborations to further develop the technology. 

“We are very excited about the prospects of this new alloy, but it requires a team from across the supply chain to make it successful. So, we are looking for partners to provide guidance for the next stages of development,” he said. 

Samples were produced and tested at RMIT’s cutting edge Advanced Manufacturing Precinct. 

‘Compositional criteria to predict columnar to equiaxed transitions in metal additive manufacturing’ is published in Nature Communications (DOI: 10.1038/s41467-025-60162-0).

A sample of the new stronger, cheaper 3D printed titanium.

Credit

Michael Quin, RMIT University

Journal

Nature Communications

DOI

10.1038/s41467-025-60162-0

Method of Research

Computational simulation/modeling

Subject of Research

Not applicable

Article Title

Compositional criteria to predict columnar to equiaxed transitions in metal additive manufacturing

Article Publication Date

1-Jul-2025

When light collides with light

Vienna University of Technology

Light collision — image:
Light is scattered by light – via virtual particles
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Credit: TU Wien

Usually, light waves can pass through each other without any resistance. According to the laws of electrodynamics, two light beams can exist in the same place without influencing each other; they simply overlap. Light saber battles, as seen in science fiction films, would therefore be rather boring in reality.

Nevertheless, quantum physics predicts the effect of “light-on-light scattering”. Ordinary lasers are not powerful enough to detect it, but it has been observed at the CERN particle accelerator. Virtual particles can literally emerge from nothing for a short time, interact with the photons and change their direction. The effect is extremely small, but it must be understood precisely in order to verify particle physics theories through current high-precision experiments on muons. A team at TU Wien (Vienna) has now been able to show that a previously underestimated aspect plays an important role in this: the contribution of so-called tensor mesons. The new results have been published in the journal Physical Review Letters.

Virtual particles from nothing

When photons interact with photons, virtual particles can be created. They cannot be measured directly, as they disappear immediately. In a sense, they are constantly there and not there at the same time – quantum physics allows such superpositions of states that would be mutually exclusive according to our classical everyday understanding.

“Even though these virtual particles cannot be observed directly, they have a measurable effect on other particles,” says Jonas Mager from the Institute of Theoretical Physics at TU Wien, lead author of the study. “If you want to calculate precisely how real particles behave, you have to take all conceivable virtual particles into account correctly. That's what makes this task so difficult – but also so interesting.”

When light scatters off light, a photon may transform, for example, into an electron-positron pair. Other photons can then interact with these two particles before the electron and positron annihilate each other and become a new photon. Things become more complicated when heavier particles are created that are also subject to strong nuclear forces – for example, mesons, which consist of a quark and an antiquark.

“There are different types of these mesons,” says Jonas Mager. “We have now been able to show that one of them, the tensor mesons, has been significantly underestimated. Through the effect of light-light scattering, they influence the magnetic properties of muons, which can be used to test the Standard Model of particle physics with extreme accuracy.” Tensor mesons did appear in earlier calculations, but with very rough simplifications. In the new evaluation, not only does their contribution turn out to be much stronger than previously assumed, but it also has a different sign than previously thought, thus influencing the results in the opposite direction.

Unusual theoretical methods

This result also resolves a discrepancy that arose last year between the latest analytical calculations and alternative computer simulations. “The problem is that conventional analytical calculations can describe the strong interactions of quarks only well in limiting cases,” says Anton Rebhan (TU Wien).

The TU Wien team, on the other hand, used an unconventional method – holographic quantum chromodynamics. This involves mapping processes in four dimensions (i.e. three spatial dimensions and one time dimension) onto a five-dimensional space with gravity. Some problems can then be solved more easily in this other space, and the results are then transformed back again. “The tensor mesons can be mapped onto five-dimensional gravitons, for which Einstein's theory of gravity makes clear predictions,” explains Anton Rebhan. "We now have computer simulations and analytical results that fit well together but deviate from certain previous assumptions. We hope that this will also provide new impetus to accelerate already planned specific experiments on tensor mesons."

The standard model put to the test

These analyses are important for one of the biggest questions in physics: How reliable is the Standard Model of particle physics? This is the generally accepted quantum physical theory that describes all known types of particles and all forces of nature – except gravity.

The accuracy of the Standard Model can be investigated particularly well in a few special test cases, for example by measuring the magnetic moment of muons. For many years, scientists have been puzzling over whether certain discrepancies between theory and experiment point to “new physics” beyond the Standard Model, or whether they are simply inaccuracies or errors. The discrepancy in the muon magnetic moment has recently become much smaller – but in order to really search for new physics, the remaining theoretical uncertainties must also be understood as precisely as possible. This is exactly what the new work contributes to.

Journal

Physical Review Letters

DOI

10.1103/dxwr-gpsl

Article Title

Longitudinal short-distance constraints on hadronic light-by-light scattering and tensor-meson contributions to the muon 𝑔−2

Article Publication Date

21-Jul-2025

Pioneering research reveals worldwide scale of Hepatitis C among babies and children

University of Bristol

A new study, coinciding with World Hepatitis day, has estimated for the first time the number of children born globally with hepatitis C virus.

The research, led by researchers from the National Institute for Health and Care Research (NIHR) Health Protection Research Unit in Evaluation and Behavioural Science (HPRU EBS) at the University of Bristol, estimated that each year around 74,000 children globally are born with hepatitis C virus (HCV), with around 23,000 of these children estimated to still have HCV infection at age five.

Pakistan and Nigeria were the countries shown to have the highest levels of cases, followed by China, Russia, and India, which in total were found to make up around half of all vertically transmitted infections.

The study, published in the journal Lancet Gastroenterology and Hepatology, produced estimates for each country which is a first, as previously such figures were only available for Pakistan, Egypt, and the USA using data from more than 10 years ago.

Lead author Dr Adam Trickey, Senior Research Fellow at the University of Bristol Medical School, said: “Our study findings highlight not only the scale of transmission, but also the great need for more testing. Without this testing the virus, which can be cured in most cases, is left untreated in young children who contract the virus from birth.

“These statistics are important for policymakers and healthcare planners as they uncover a major source of new HCV infections that has so far been understudied. There are also implications for service delivery, as pregnancy is often a time where it is possible for healthcare providers to engage with people who they might not usually be in contact with, offering a chance to screen them for HCV and connect them to care if necessary.”

The World Health Organization estimates that across the world there are some 50 million people living with HCV, a bloodborne virus, and that around 240,000 people died of hepatitis C-related liver disease in 2022.

Dr Trickey added: “This is despite highly effective treatments for HCV being available in many countries since 2014. These treatments involve a course of pills that need to be taken for around three months, with effective cure rates of more than 90%.”

This new study combined estimates of the number of women aged 15-49 with HCV in each country, with new estimates of the probability of transmission of HCV to the child whilst the mother is pregnant, which is around 7% per birth. The researchers also accounted for new estimates of the proportion of children born with HCV who will naturally clear the virus before they reach five-years-old, which is high at around two-thirds.

Hepatitis C is generally concentrated among marginalised populations, for example people who inject drugs or those exposed to unsterile medical procedures. In 2022 the World Health Organization reported that only around a third (36%) of people with HCV were aware of their infection. This is partially because HCV can have few or no symptoms for many years and then eventually result in severe liver-related issues such as cirrhosis and cancers of the liver. More testing is therefore needed in most populations to identify who has hepatitis C.

American and European HCV guidelines now recommend screening for all pregnant women. However, screening among pregnant women is uncommon in most settings, including where it is recommended.

Recommendations for treatment of HCV in children vary, but guidelines mostly indicate children can be treated from the age of three years onwards.

Dr Trickey added: “Most guidelines do not advise for pregnant women with HCV to be treated because of a lack of evidence of the safety of these treatments, although a clinical trial is currently investigating this – preliminary results indicate high cure rates and few major side effects.

“Given the availability of effective medicine, and further progress in this field, it’s vital that testing and diagnosis rates improve so more people can be treated and cured.”

Journal

The Lancet Gastroenterology & Hepatology

Subject of Research

People

Article Title

‘Estimating the annual number of hepatitis C virus infections through vertical transmission at country, regional, and global levels: a data synthesis study’

Article Publication Date

29-Jul-2025

Study finds that white students visit college advisers the least, but benefit most in terms of graduation rates and GPA

Research challenges assumptions that college students of color have less successful academic outcomes because they are less likely to pursue institutional support

New York University

A new study finds that White students visit academic advisers the least, but have the highest academic benefits, in terms of GPA and graduation rates, compared to nonwhite students and international students.

In higher education, substantial gaps exist between White and nonwhite students, with a greater number of White students graduating in fewer years and receiving higher grades than many other groups. Prior research shows that nonwhite students are less likely to engage with faculty members, but there is a dearth of information related to interactions with academic advisers—staffers who provide guidance related to courses needed for graduation, resources, and career pathways.

“Academics, practitioners, and policymakers alike have purported that academic advising is a powerful mechanism to close some of these gaps and that marginalized students attend advising meetings the least. In many ways, we find the opposite of these arguments,” says Hua-Yu Sebastian Cherng, the study’s lead author and associate professor of international education at NYU Steinhardt School of Culture, Education, and Human Development.

Using 2017-2021 data from a US university with one of the largest undergraduate populations, Cherng and his co-authors analyzed student achievement (grades, graduation rates), demographics (race/ethnicity, income, international status, and first-generation status), and appointments with advisers. They evaluated outcomes for different demographic groups as well as differences within groups.

They found that nonwhite and international student groups (with the exception of students who identified their race as “other”) met with advisers more frequently than White students from the US. Despite meeting with advisers more often, students of color received fewer benefits. For example, White students who had one advising meeting had roughly 0.05 point higher GPAs than their White peers who had no advising meetings, while there were no differences among Latine students. While many groups experienced GPA benefits to advising (with the exception of Latine students), graduation rates were only higher for White students.

In terms of social class, first-generation students were seven percent less likely to meet with advisers and less likely to graduate than students whose parents attended college. There were no differences found in outcomes between low- and high-income students.

Their findings are published in Educational Researcher.

“Our study highlights the importance of advising: it does have an impact, but the question now should be for whom,” says Cherng. “Efforts should be paid to the substance of advising and how advisors work with different groups of students. Only in this way can advising fulfill its purpose as an equalizing force.”

This study is co-authored by Junhow Wei, assistant dean for studies, Princeton University, and Martha Moreno, postdoctoral fellow, New York University.

This study was funded by the Spencer Foundation.

Journal

Educational Researcher

DOI

10.3102/0013189X251356501

Method of Research

Data/statistical analysis

Subject of Research

People

Article Title

Is Meeting Enough? Differences in Frequency and Consequences of Academic Advising Appointments Between Marginalized and Mainstream College Students

Article Publication Date

28-Jul-2025