<![CDATA[Newsroom University of Manchester]]> /about/news/ en Tue, 14 Jul 2026 15:48:34 +0200 Thu, 09 Jul 2026 13:20:43 +0200 <![CDATA[Newsroom University of Manchester]]> https://content.presspage.com/clients/150_1369.jpg /about/news/ 144 New learning tool speeds up search for 2D quantum materials /about/news/new-learning-tool-speeds-up-search-for-2d-quantum-materials/ /about/news/new-learning-tool-speeds-up-search-for-2d-quantum-materials/762743This research was published in the journal Science Advances.

Discovery of flat-band 2D materials via physics-informed scoring and structure-based learning

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A new physics-informed machine-learning method could help researchers find two-dimensional materials with unusual electronic properties more quickly and with fewer calculations.

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A new physics-informed machine-learning method could help researchers find two-dimensional materials with unusual electronic properties more quickly and with fewer calculations. 

Researchers at The University of Manchester have developed a new computational approach to help identify two-dimensional materials that may host unusual quantum behaviour. The work, published in focuses on materials with “flat bands”, electronic states where electrons have very little kinetic energy. In these materials, interactions between electrons can become much more important, creating conditions linked to phenomena such as magnetism, unconventional superconductivity and topological electronic behaviour.  

Finding real materials with flat bands from large dataset is difficult. Conventional searches often rely on density functional theory calculations, which can reveal a material’s electronic structure but are time-consuming when applied across thousands of possible candidates. The Manchester team took a different route. They developed a physics-informed scoring system that captures two signatures of flat-band behaviour, low band dispersion and a strong peak in the density of states, then trained a model to estimate that score directly from atomic structure. 

“Flat bands are not only a feature we see in electronic calculations. They are often connected to the geometry of atoms in a material.” said Dr Xiangwen Wang, leading author of the study. “Our approach learns from that structure, which means we can search much larger materials spaces in a more targeted and interpretable way.” 

The framework was trained using known two-dimensional materials and then applied to more than 10,000 unlabelled 2D materials. Among high-scoring candidates with kagome-like structural motifs, follow-up quantum calculations confirmed flat-band behaviour with 98.2% accuracy. The study also identified several materials predicted to host fragile topological flat bands, a form of electronic topology associated with strongly correlated quantum phases. These results suggest that the method can do more than sort large datasets, it can help reveal which structural features make certain materials promising for further study. 

, Senior Research Fellow in the  at The University of Manchester, said: “The exciting part is not only that we found new candidate materials, but that the method changes how we search. Rather than calculating everything first and looking afterwards, we can now use physical intuition and structural learning to guide the search from the beginning. That makes discovery more scalable and more interpretable.” 

The approach remains computational, so experimental work will be needed to test the most promising candidates in the laboratory. However, the researchers say the same strategy could be adapted to search for other classes of quantum materials, provided the target property can be expressed as a meaningful physics-based score. By connecting physical insight with structure-based learning, the study offers a more efficient way to move from large materials databases to shortlists of candidates for detailed quantum calculations and experimental validation. 

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Cheaper catalytic system turns captured carbon into ethanol /about/news/cheaper-catalytic-system-turns-captured-carbon-into-ethanol/ /about/news/cheaper-catalytic-system-turns-captured-carbon-into-ethanol/762533Journal: Catalysis Science & Technology   

Full title: Synthesis of ethanol via methanol homologation with CO₂ and H₂ using an industrially relevant Ru–Co catalyst  

DOI: 10.1039/D6CY00285D 

URL: 

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Researchers have developed a catalyst system that converts methanol, carbon dioxide and hydrogen into ethanol using stable, commercially available catalyst precursors, offering a potential route towards lower-cost industrial production.  

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An international team of researchers has developed a homogeneous catalytic process that converts methanol, carbon dioxide and hydrogen into ethanol using inexpensive and stable catalyst precursors. 

Published in Royal Society of Chemistry’s , the study addresses a key challenge in efforts to transform captured carbon dioxide into useful chemicals. While ethanol can be produced from carbon dioxide and hydrogen, many existing homogeneous catalytic systems rely on expensive or complex catalyst precursors that can be difficult to deploy at industrial scale. 

In the study – a collaboration between researchers from The University of Manchester, the Institute of Chemistry, Chinese Academy of Sciences, the University of Chinese Academy of Sciences, Tianjin University of Science and Technology, and Fuzhou University - the team designed a homogeneous catalytic system using commercially available ruthenium chloride hydrate and cobalt chloride hexahydrate. After activation with carbon monoxide, the catalyst converted methanol, carbon dioxide and hydrogen into ethanol under relatively mild reaction conditions of 170°C. 

Under optimised conditions, the catalyst achieved an ethanol selectivity of 64.9% and an ethanol space-time yield of 3.9 g L⁻¹ h⁻¹, which the authors report is higher than previous ruthenium-cobalt catalyst systems used for this type of reaction.

Ethanol is one of the world's most widely used chemicals. It is used in fuels, solvents, disinfectants and as a feedstock for manufacturing. Finding new ways to produce ethanol from carbon-containing waste streams could help support broader efforts to make chemical production less dependent on fossil resources. The study focused on a process in which methanol acts as a starting material and carbon dioxide provides an additional carbon source. 

The team also investigated how the catalyst works. Their experiments showed that carbon dioxide is first converted into carbon monoxide through a reverse water gas shift reaction. The carbon monoxide then acts as an intermediate in forming ethanol. The researchers found that ruthenium and cobalt perform complementary roles, with ruthenium helping drive hydrogenation steps and cobalt promoting the carbon-carbon bond formation needed to build the ethanol molecule. 

Beyond performance, the researchers assessed characteristics important for industrial use. The activated catalyst remained stable during storage tests and retained good activity after five recycling cycles. The catalyst system also uses precursor materials that are easier to obtain and store than many alternatives previously reported for similar reactions. 

The work has already progressed to preliminary scale-up studies. The authors report that the catalyst maintained high activity and ethanol selectivity in larger-scale reactor (3 L). Based on these findings, the team proposed a process flow for producing ethanol from methanol, carbon dioxide and hydrogen, with catalyst recycling and recovery of unreacted materials built into the design. 

i adds: “There is still further work to do before a process such as this could be implemented commercially. However, these results demonstrate a promising route that combines accessible catalyst materials with recyclability and strong performance, which are all important considerations when developing practical carbon utilisation technologies.” 

This international collaboration was funded by the National Key Research and Development Program of China (Grant No. 2024YFE0206500) from MOST International S&T Cooperation Centre.

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Tue, 07 Jul 2026 20:28:45 +0100 https://content.presspage.com/uploads/1369/2b279a62-2028-4749-80c2-aa6e458c30c7/500_synthesisofethanolviamethanolhomologationwithco2andh2usinganindustriallyrelevantrundashcocatalyst.png?10000 https://content.presspage.com/uploads/1369/2b279a62-2028-4749-80c2-aa6e458c30c7/synthesisofethanolviamethanolhomologationwithco2andh2usinganindustriallyrelevantrundashcocatalyst.png?10000
Manchester-led research shows how the cultural sector can accelerate city climate action in cities /about/news/manchester-led-research-shows-how-the-cultural-sector-can-accelerate-city-climate-action-in-cities/ /about/news/manchester-led-research-shows-how-the-cultural-sector-can-accelerate-city-climate-action-in-cities/762454Liverpool’s year as the first UN Climate Change Accelerator City has shown that the cultural sector can be a powerful driver of climate action, but cities need the right expertise, data, governance and infrastructure to deliver lasting change, according to a new report.

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Liverpool’s year as the first UN Climate Change Accelerator City has shown that the cultural sector can be a powerful driver of climate action, but cities need the right expertise, data, governance and infrastructure to deliver lasting change, according to a

The evaluation, led by researchers at The University of Manchester’s Tyndall Centre for Climate Change Research and Centre for Climate Change and Social Transformations (CAST), analysed nine real-world pilot projects spanning music festivals and arena concerts, TV production, infrastructure and public transport.

The findings show that the Programme delivered practical changes with the potential for long term impact across Liverpool’s cultural sector, including new sustainability standards for film and TV production, improved carbon reporting at events and greener operational practices in the city’s major venues.

The programme delivered a series of high-profile successes, including:

  • Liverpool's M&S Bank Arena was recognised by A Greener Future as one of the UK's greenest music venues after trialling fully plant-based catering, improved waste management and shared production infrastructure across a series of major concerts.

  • Two BBC drama productions filmed in Liverpool – The Cage and Waiting for the Out – reported reductions in their carbon footprints of 46% and 61% compared to the industry average through measures including LED lighting, battery power and dedicated staff with sustainability expertise.

  • BBC Radio 1's Big Weekend won the Green d at the UK Festival ds after introducing battery-powered infrastructure, low-carbon travel initiatives and the most comprehensive environmental dataset ever collected for the festival.

  • The UK's first National Occupational Standards for sustainability roles in film and television were developed through consultation with industry professionals.

Beyond individual pilots, the research found that the programme changed how sustainability was considered within Liverpool City Council, improving understanding and confidence around sustainability, helping embed climate considerations in everyday decision-making and future cultural project planning.

Local authorities were found to have particular influence through using the levers already within their direct control, such as land-use and event permissions. In Liverpool, this led to the development of a new framework for events on council land, embedding environmental standards and data reporting into the approvals process.

Liverpool’s UN ‘Accelerator City’ status also provided momentum, helping bring together organisations across the creative industries to collaborate in ways that might have been difficult under normal circumstances.

However, the research also highlights the significant barriers and challenges cities face when trying to cut emissions.

A lack of funding, limited staff capacity and gaps in technical expertise slowed progress across several projects. In many cases, basic data on environmental impacts was missing, making it harder to target the most effective actions.

Efforts to introduce low‑carbon infrastructure during the year, such as replacing diesel generators or improving grid connections, were constrained by the cost, complexity and time needed to modernise existing systems.

Interventions that depended on external partners, such as integrating public transport, proved significantly harder to deliver at pace trials helped to identify challenges and opportunities and a plan for how this can be operationalised in the future has been developed.

The researchers say that the lessons are relevant far beyond a single city and the findings can help any city or cultural organisation reduce emissions.

Read the full report here:

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Tue, 07 Jul 2026 11:36:53 +0100 https://content.presspage.com/uploads/1369/a7cacc51-2c9d-4d06-9fe3-b07f400029fd/500_un-accelerator-city-picture.jpg?10000 https://content.presspage.com/uploads/1369/a7cacc51-2c9d-4d06-9fe3-b07f400029fd/un-accelerator-city-picture.jpg?10000
Manchester astronomers celebrate launch of the "universe’s greatest movie" /about/news/manchester-astronomers-celebrate-launch-of-the-universes-greatest-movie/ /about/news/manchester-astronomers-celebrate-launch-of-the-universes-greatest-movie/762449Manchester astronomers are celebrating the launch of the Rubin Legacy Survey of Space and Time (LSST) which began last week from a mountaintop in Chile.

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Manchester astronomers are celebrating the launch of the Rubin Legacy Survey of Space and Time (LSST) which began last week from a mountaintop in Chile.

After more than a decade of preparations, it’s the start of one of the most ambitious studies of the cosmos ever undertaken. For the next ten years, the LSST will capture the entire southern sky to create an ultra-wide, ultra-high-definition time-lapse record of our Universe. This movie will help solve some of the Universe’s biggest mysteries – such as the nature of dark energy, and the evolution of the solar system, Milky Way, and galaxies across cosmic time.

The University of Manchester is part of the , a partnership of 36 institutions representing the UK’s leading astronomy research groups. Supported by investment from the (STFC), 

Scientists at Manchester will use Rubin data to study the first galaxies and the evolution of the universe and its cosmological parameters.  

During its 10-year survey, Rubin will catalogue an estimated 17 billion stars, 20 billion galaxies, and millions of events that change in the sky – more objects than there are living people on earth. With the survey expected to create up to 500 petabytes of data in its lifetime, the UK is playing a significant role in the management and processing of this unprecedented dataset. The UK's LSST data facility will process 25% of the data from Rubin, turning raw images of the sky into the calibrated data products with which astronomers can do science, and will operate a science platform capable of supporting analysis of those data products by 20% of the international LSST community.

The UK's LSST computing facility also hosts the Lasair event broker, a sophisticated software system supporting the near-real-time analysis of the alerts that Rubin issues whenever it detects a moving or time-varying celestial source. This alert stream - which can comprise millions of alerts per night and which includes a wide range of astrophysical objects, from nearby asteroids to distant supernovae - started flowing in February, ahead of today's formal start of the 10-year LSST.

Professor Grahame Blair, Executive Director of Programmes at STFC, said: "Today marks the beginning of a new era in astronomy. Together with our partners, UK scientists, engineers and software experts, STFC is excited to be part of one of the most ambitious scientific projects ever undertaken. “The discoveries made over the next decade will inspire future generations, deepen our understanding of the cosmos, and reinforce the UK's position at the forefront of astronomical research."

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Tue, 07 Jul 2026 11:17:34 +0100 https://content.presspage.com/uploads/1369/68dc17ed-860f-4eda-92f6-0f3099e27b12/500_oceanofstars.creditnsfndashdoeverac.rubinobservatorynoirlabslacaura.jpg?10000 https://content.presspage.com/uploads/1369/68dc17ed-860f-4eda-92f6-0f3099e27b12/oceanofstars.creditnsfndashdoeverac.rubinobservatorynoirlabslacaura.jpg?10000
Manchester scientists observe water’s behaviour in a single molecular layer /about/news/manchester-scientists-observe-waters-behaviour-in-a-single-molecular-layer/ /about/news/manchester-scientists-observe-waters-behaviour-in-a-single-molecular-layer/757846This research was published in the journal Nature Communications.

Sub-diffractional infrared absorption of two-dimensional water

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New research has revealed that water behaves differently when confined to spaces just one molecule thick. For the first time, scientists have directly measured the vibrational signatures of truly two-dimensional water. In a study published recently in , researchers used ultra-thin channels only a few angstroms high to trap water in isolated layers and probe how its hydrogen-bonding network changes under extreme confinement. 

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New research has revealed that water behaves differently when confined to spaces just one molecule thick. For the first time, scientists have directly measured the vibrational signatures of truly two-dimensional water. In a study published recently in , researchers used ultra-thin channels only a few angstroms high to trap water in isolated layers and probe how its hydrogen-bonding network changes under extreme confinement. 

Researchers from Professor Radha Boya’s team in The University of Manchester’s Department of Physics and the , working with Diamond Light Source and Freie Universität Berlin, found that water reorganises in surprising ways at the smallest molecular scales. Hydrogen bonds give water many of its familiar properties, but until now it has been extremely difficult to test what happens when water is forced into a flat, single-layer arrangement because the amount of material is so small. 

By combining atomically precise nanochannels with the ultra-bright synchrotron infrared microbeam at Diamond Light Source’s , the team was able to measure the vibrational modes of water confined down to a single molecular layer. 

 from The University of Manchester said: “You can think of bulk water as a three-dimensional network where each molecule is constantly forming and breaking hydrogen bonds in all directions. When you squash water into a single layer, that network simply cannot hold together in the same way. For the first time, we were able to directly see how those bonds rearrange in this extreme limit.” 

The researchers created angstrom-scale slit channels using stacks of two-dimensional materials, including graphite and hexagonal boron nitride. These materials acted as both atomically smooth confining walls and optical amplifiers, boosting the weak infrared absorption signal from just a single layer of water. 

Infrared spectroscopy is highly sensitive to the stretching vibrations of O-H bonds within water molecules. By comparing water in channels of different heights with water in bulk regions of the same device, the researchers tracked how those vibrational frequencies changed as the water layer became thinner, down to a monolayer. 

The team found that when water is confined to a true monolayer, its infrared absorption spectrum shifts to higher frequencies. Dr Gianfelice Cinque of Diamond Light Source said: “My first excitement was being able to measure, at beamline B22, the vibrational fingerprint of a single monolayer of water. To our knowledge, this is the first time that the transition from 3D to 2D water has been directly detected with an infrared microprobe. The blue shift is a clear sign that the hydrogen-bonding network is disrupted compared with bulk water.” 

“Our measurements show that monolayer water does not resemble a flat version of ordinary liquid water,” added Professor Boya. “Instead, it forms a fragmented, mosaic-like structure made up of small hydrogen-bonded clusters surrounded by poorly bound or free molecules.” 

The study also showed that this behaviour is specific to the monolayer limit. Once the channels exceeded around one nanometre in height, equivalent to roughly three molecular layers of water, the vibrational signatures began to move back towards those of bulk water, indicating recovery of a more conventional hydrogen-bond network.

To understand the origin of these spectral changes, the experiments were supported by atomistic simulations. Professor Roland Netz of Freie Universität Berlin said: “Despite the disrupted bonding, monolayer water is unexpectedly dense and structurally distinct from both bulk water and simple interfacial water at surfaces.” 

The findings provide direct experimental evidence for long-standing theoretical predictions about two-dimensional water and offer a benchmark for future studies of confined fluids. 

Dr Marcos Martins, first author of the study at The University of Manchester, said: “Water confined at this scale plays a role in everything from nanofluidic devices to biological channels and energy technologies. Having a direct experimental picture of how its structure changes at the single-layer limit helps us understand the physical rules that govern these systems.” 

The ability to directly measure how water reorganises at the single-layer limit could help researchers design better angstrom-scale technologies, including nanofluidic circuits, selective membranes, and electrochemical and energy devices where confined water shapes interfacial behaviour. The same platform could also be used to study other ultrathin liquids and solvated ions, expanding experimental access to extreme confinement in materials science and biology. 

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Fri, 03 Jul 2026 11:00:00 +0100 https://content.presspage.com/uploads/1369/febda2c7-1cbd-44a4-8d44-09550ef59580/500_img_1987.jpeg?10000 https://content.presspage.com/uploads/1369/febda2c7-1cbd-44a4-8d44-09550ef59580/img_1987.jpeg?10000
University of Manchester to lead BioFAIR's first national Methods Commons /about/news/university-of-manchester-to-lead-biofairs-first-national-methods-commons/ /about/news/university-of-manchester-to-lead-biofairs-first-national-methods-commons/762117The University of Manchester will play a leading role in delivering new national infrastructure for UK life sciences.

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The University of Manchester will play a leading role in delivering new national infrastructure for UK life sciences.

The University and the Earlham Institute have been appointed by BioFAIR to lead a new consortium to establish the Methods Commons, the first spoke of the £34 million BioFAIR programme.

The Methods Commons will provide researchers with national-scale capabilities for the discovery, execution, sharing and reuse of the computational workflows, tools and notebooks that underpin modern data-driven life sciences.

Led by Professor Carole Goble at The University of Manchester, the consortium will develop services designed to improve the reproducibility, reliability and reuse of computational methods across UK bioscience.

The Methods Commons will deliver eight core capabilities for UK life sciences researchers, including Galaxy and Nextflow workflow execution, support for containerised bespoke workflows on HPC, a national workflow registry with a community-endorsement mechanism, a “workflow observatory” providing trust and quality assurance, a shared Jupyter notebook environment, and API standards for ingesting input data and sharing workflow results.

Tony Burdett, BioFAIR Director, said: “The Methods Commons tackles one of the longest-standing problems in computational bioscience — reproducibility and reuse of methods that produce the results to be included in publications as research outputs. We had a strong field of applicants, and the appointed consortium combines real delivery track record with deep roots in the UK and international workflow communities. Establishing the Methods Commons is a major milestone for BioFAIR as it’s the first spoke in our federated BioCommons and the point at which the services needed by our users really start to take shape.”

The consortium — which includes support from Nextflow, Seqera — was selected following a competitive two-stage process that opened with an Expression of Interest call in December 2025, followed by invited full proposals reviewed by an independent expert panel. BioFAIR is investing up to £4 million over an initial two-year period, with the expectation that the partnership will extend to deliver the full programme of work through to June 2029 and beyond.

, Methods Commons Project Lead, said: “We’re proud to be establishing the Methods Commons as part of BioFAIR. Computational workflows are how modern bioscience gets done, and giving UK researchers a trusted, national-scale set of services to find, run and share them — without having to reinvent the plumbing each time — is overdue. We’re looking forward to working with the BioFAIR Hub, the Fellows and Pathfinder Projects to make sure what we build is shaped by real user needs from day one.”

The Methods Commons will adopt an incremental, user-driven delivery model, with early value delivered to exemplar communities — including the first cohort of BioFAIR Pathfinder Projects — before scaling to national reach. It will operate alongside the forthcoming Data Commons, People Commons, Knowledge Hub and BioFAIR Portal in a hub-and-spokes federated infrastructure coordinated from the BioFAIR Hub at the Earlham Institute.

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Thu, 02 Jul 2026 15:08:40 +0100 https://content.presspage.com/uploads/1369/d110a33f-bd59-49c1-9f9c-230b27adb5c9/500_digitalmolecularstructureconcept.creditblackjack3d.jpg?10000 https://content.presspage.com/uploads/1369/d110a33f-bd59-49c1-9f9c-230b27adb5c9/digitalmolecularstructureconcept.creditblackjack3d.jpg?10000
University of Manchester experts give evidence to MPs on the environmental impact of AI and data centres /about/news/university-of-manchester-experts-give-evidence-to-mps-on-the-environmental-impact-of-ai-and-data-centres/ /about/news/university-of-manchester-experts-give-evidence-to-mps-on-the-environmental-impact-of-ai-and-data-centres/761984Researchers from The University of Manchester are advising Parliament on the growing energy and environmental impacts of artificial intelligence (AI) and data centres, as part of a new inquiry into their implications for the UK’s net zero ambitions.

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Researchers from The University of Manchester are advising Parliament on the growing energy and environmental impacts of artificial intelligence (AI) and data centres, as part of a new inquiry into their implications for the UK’s net zero ambitions.

Data centres have been designated as critical national infrastructure due to their importance for economic growth, but their electricity consumption is projected to quadruple by 2030. The inquiry will assess how this increasing demand could affect energy and water systems and how emerging technologies and policy approaches could reduce environmental impacts.

In their , and researchers at the University’s Tyndall Centre for Climate Change Research, highlight a number of challenges associated with this growth, including:

  • Rising carbon emissions from both electricity use and the manufacturing of hardware

  • Increasing demand for critical materials such as copper, silicon and rare elements

  • Growing volumes of electronic waste driven by rapid hardware replacement cycles

  • Potential strain on water resources and local environments

They argue that current policies do not yet fully account for the pace and scale of AI-driven demand and recommend:

  • Integrating data centre growth into wider energy, infrastructure and environmental planning, ensuring expansion is aligned with grid capacity and the availability of low-carbon electricity.

  • Improve transparency around environmental impacts through better reporting of energy, water and material use, alongside accounting for full lifecycle of digital infrastructure, such as hardware production, supply chains and electronic waste.

  • Support a circular economy approach to digital technologies, promoting the reuse, repair, refurbishment and recycling of servers and other hardware to reduce resource demand and waste.

  • Manage the resource pressures associated with AI and data centre expansion, including demand for critical minerals

The evidence highlights emerging technologies that could reduce environmental impacts, including more efficient chips, advanced cooling systems and “green AI” approaches that limit unnecessary computation.

The researchers also point to opportunities for data centres to contribute to local energy systems, for example, by recovering waste heat to supply homes and buildings, or by providing flexibility to help balance electricity demand.

Dr Alejandro Gallego Schmid said: “Data centres are fundamental to the digital economy and will play an important role in enabling AI innovation. However, their expansion needs to be planned alongside the UK’s wider sustainability objectives.

“Our evidence shows that solutions are available but many of these will require investment in infrastructure and more coordinated action across policy, industry and research.”

Dr Alejandro Gallego Schmid delivered the evidence to the to the Environmental Audit Committee in Westminster today (1 July 2026).

The submission has been supported by , the University’s policy engagement unit.

Read the full written submission:

Read more about the inquiry:

 

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Wed, 01 Jul 2026 17:30:00 +0100 https://content.presspage.com/uploads/1369/600ab491-d2c6-409d-8dae-3846652533b8/500_moderndatacenterwithserverrackswithvfxanimationofdataflowinternettrafficonservers.creditevgeniyshkolenko.jpg?10000 https://content.presspage.com/uploads/1369/600ab491-d2c6-409d-8dae-3846652533b8/moderndatacenterwithserverrackswithvfxanimationofdataflowinternettrafficonservers.creditevgeniyshkolenko.jpg?10000
University of Manchester and UKNNL sign landmark nuclear partnership agreement /about/news/university-of-manchester-and-uknnl-sign-landmark-nuclear-partnership-agreement/ /about/news/university-of-manchester-and-uknnl-sign-landmark-nuclear-partnership-agreement/761926The University of Manchester and United Kingdom National Nuclear Laboratory (UKNNL) have signed a Memorandum of Understanding (MoU) formalising a wide-ranging partnership to advance nuclear science, grow the UK's nuclear workforce, and strengthen the country's position as a global leader in nuclear technology.

The agreement was signed at The University of Manchester by UKNNL Chief Executive Officer Julianne Antrobus and Professor Sarah Sharples, Vice President and Dean of the Faculty of Science and Engineering.

The MoU sets out a shared commitment to collaboration across decommissioning research, materials science, nuclear fuels and energy systems, waste management, and innovation — building on a relationship stretching back many years.

Julianne Antrobus, CEO, UKNNL, said: "I am looking forward to our collaboration with the University of Manchester moving from strength to strength as we work together to develop the next generation of nuclear talent and technology.

"The 2024 Strategic Review gave us a clear direction: become the partnerships-led national laboratory that government and the sector needs. One of the most important things we can do in pursuit of that is to work strategically with the academic institutions that can genuinely help us deliver our mission. The University of Manchester is one of those vitally important institutions. This MoU formalises a relationship that is already delivering world-leading science and growing the next generation of nuclear talent — and it signals our intent to do much more together. Our partnership with Manchester, alongside our recent agreements with CEA, Bangor University, JAEA and Rolls-Royce, positions UKNNL at the centre of a network of world-class partners, so that we can deliver on our purpose: nuclear science to benefit society."

Professor Sarah Sharples, Vice President and Dean of the Faculty of Science and Engineering, University of Manchester, said: “This Memorandum of Understanding marks an exciting new chapter in the growing partnership between UKNNL and The University of Manchester. By bringing together our expertise in nuclear science, research and education, we are creating new opportunities to develop talent, advance innovation and address some of the most important challenges facing the UK’s nuclear sector. We look forward to working together to inspire the next generation and deliver meaningful impact through collaboration."

Professor Zara Hodgson, Director of the Dalton Nuclear Institute, said: “I am delighted to see this MoU between UKNNL and The University of Manchester signed today. It provides us with a firm platform for a renewed and strengthened collaborative approach to serve the sector. Enabling our teams to work together more closely is a foundational step towards progress in vital research and innovation for a transforming sector and to  achieve an accelerated pathway to nuclear expertise that the sector needs now, and in the future.

About the agreement

The MoU formalises collaboration across six priority areas:

  • decommissioning of engineered facilities;
  • advanced materials performance and degradation for future nuclear systems;
  • improved fuels and fuel manufacturing routes for current and future reactors;
  • waste management including land quality, effluent treatment, decontamination and disposal;
  • innovation and translation of research to industrial deployment;
  • growing the as a globally recognised centre of expertise.

The agreement also establishes arrangements for sharing facilities and expertise, including access to UKNNL's Preston and Central Laboratory facilities for Manchester PhD students and researchers, and reciprocal access to University facilities for UKNNL staff.

A track record of collaboration

The two organisations have an established history of joint working that is already delivering results for the UK nuclear sector, including published research in leading journals on nuclear fuels and materials, support for PhD researchers in next-generation nuclear technologies, shared personnel arrangements including visiting and honorary academic appointments, and the establishment of centres of excellence such as the Effluents Centre of Excellence and the PHLAME (Photonics and Laser Analysis of Materials and Environments) collaborative research group.

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Manchester researchers uncover how to turn plant waste into valuable chemicals more efficiently /about/news/turning-plant-waste-into-valuable-chemicals-more-efficiently/ /about/news/turning-plant-waste-into-valuable-chemicals-more-efficiently/761796Researchers at The University of Manchester and Hebei University of Technology have identified how a new class of catalyst can break down lignininto useful chemical building blocks offering a more sustainable route to replace fossil-based materials.Researchers at The University of Manchester in collaboration with Hebei University of Technology have identified how a new class of catalyst can break down lignin – one of the most abundant components of plant biomass – into useful chemical building blocks, offering a more sustainable route to replace fossil-based materials.

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Lignin is a key structural component of plants, the largest renewable source of aromatic chemicals in nature, and is present in appreciable levels (up to 35%) in waste biomass, including that from agriculture and forestry sectors. However, its complex structure makes it difficult to break down efficiently, limiting its use in sustainable manufacturing.

In a study published in , the international research team including Xinyue Zhou, and from the Department of Chemical Engineering, has aided in revealing how a highly efficient “single-atom catalyst” species operates at the molecular level to cleave the strong chemical bonds that hold lignin together.

The catalyst uses isolated ruthenium atoms embedded in a nitrogen-doped carbon material. This design maximises catalytic performance while using very small amounts of metal, making it more efficient than conventional systems

A clearer picture of how lignin breaks apart

A major challenge in this field has been understanding exactly which parts of the catalyst are responsible for breaking lignin’s tough chemical bonds. Without this knowledge, improving catalyst performance has remained difficult.

The research shows that a specific atomic configuration – known as a “Ru–N₄ site” – plays a central role. These sites activate oxygen molecules and help drive the cleavage of both carbon–oxygen and carbon–carbon bonds within lignin.

By combining experimental techniques with computational modelling, the team demonstrated how the catalyst first activates oxygen to form highly reactive species, which then attack the lignin structure and break it down into smaller molecules.

High efficiency under mild conditions

Under optimised conditions, the catalyst achieved near-complete conversion of model lignin compounds and produced high yields of valuable phenolic chemical products.

Importantly, the system operates under relatively mild conditions and without the need for harsh chemicals, highlighting its potential for more sustainable chemical manufacturing processes.

The catalyst was also successfully applied to real lignin samples from different biomass sources, converting them into useful aromatic compounds that could serve as building blocks for fuels, plastics and other materials.

Toward sustainable chemical production

This work provides a detailed understanding of how single-atom catalysts function in biomass conversion, offering a blueprint for designing more efficient systems in the future.

By enabling the upgrading and valorisation of lignin, the research supports efforts to move away from traditional linear petroleum-derived chemicals and towards a more circular, biomass-based economy.

This research was published in: ACS Catalysis

Full title of the paper: Unveiling the Role of Ru–N4 on Ru–N–C Single-Atom Catalyst in C–O/C–C Bonds’ Oxidative Cleavage in Lignin

DOI: 10.1021/acscatal.5c08001

URL: https://pubs.acs.org/doi/10.1021/acscatal.5c08001

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Wed, 01 Jul 2026 09:30:00 +0100 https://content.presspage.com/uploads/1369/27b49eb6-7834-48cc-893d-9cf30781b367/500_ligninrusac_1920x1080.jpg?10000 https://content.presspage.com/uploads/1369/27b49eb6-7834-48cc-893d-9cf30781b367/ligninrusac_1920x1080.jpg?10000
University of Manchester research supports major WHO update on global air pollution /about/news/university-of-manchester-research-supports-major-who-update-on-global-air-pollution/ /about/news/university-of-manchester-research-supports-major-who-update-on-global-air-pollution/761833A researcher from The University of Manchester has contributed to a major World Health Organization (WHO) update revealing that global progress on reducing air pollution has slowed, with low- and middle-income countries continuing to face the greatest risks. 

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A researcher from The University of Manchester has contributed to a major World Health Organization (WHO) update revealing that global progress on reducing air pollution has slowed, with low- and middle-income countries continuing to face the greatest risks. 

The new estimates, published by the WHO as part of its monitoring of the UN Sustainable Development Goals (SDGs), shows that while levels of fine particulate matter (PM2.5) declined globally up to 2020, they have since remained largely unchanged. 

The new estimates will support global efforts to towards the WHO’s new goal to cut deaths linked to anthropogenic (man-made) air pollution by 50% by 2040, providing a critical evidence base for international policy and action. 

, a Lecturer in Data Science & Analytics at The University of Manchester and Research Scientist at the National Centre for Atmospheric Science, developed the Data Integration Model for Air Quality (DIMAQ) in collaboration with the World Health Organization (WHO) during his PhD. Since 2016, DIMAQ has underpinned the WHO's global estimates of population exposure to ambient air pollution. This latest release, the first since 2021, incorporates new data and methodological advances to provide the most up-to-date assessment of global air pollution trends and inequalities.

Dr Thomas’s work contributes directly to monitoring SDG indicator 11.6.2, which tracks annual levels of fine particulate matter (PM2.5) in cities, and SDG 3.9.1, which tracks the mortality rate attributable to ambient and household air pollution. 

DIMAQ brings together satellite observations, atmospheric models, and ground-based monitoring data to provide a consistent picture of air pollution levels around the world, enabling meaningful comparisons between countries.

The updated figures highlight significant disparities between countries. In 2023, exposure to PM2.5 above the WHO Air Quality Guidelines was more than 13 times higher in low- and middle-income countries than in high-income countries, affecting around 6.5 billion people worldwide.

Exposure to both ambient and household air pollution remains a major driver of non-communicable diseases, including heart disease, stroke, chronic respiratory conditions and lung cancer, with the greatest burden falling on vulnerable populations. 

Regional trends highlight mixed progress. While Asia bears the highest levels of air pollution, it also displays the greatest progress, while other regions, including Africa and Western Asia, have seen little change over the last decade. 

Urban areas typically experience higher pollution levels than rural areas, but cities have also shown stronger improvements irrespective of their income level. In contrast, some rural areas, particularly in low-income countries, have seen pollution increase. 

Bruce Gordon, Director a.i., Environment, Climate Change, One Health and Migration, WHO, said: “As the custodian of environmental health-related SDG indicators, WHO is committed to providing robust, evidence-based data, which is essential for bold decision-making. We cannot address the climate and air pollution crisis or protect public health without reliable information that highlights global inequalities and disparities. Placing science at the forefront to drive monitoring and foster multi-sectoral collaboration is crucial to ensuring universal access to clean air and energy, safeguarding both the health of people and planet—now and for future generations."

The ongoing use of Manchester-developed research highlights the University’s contribution to tackling one of the world’s most pressing environmental health challenges. 

The work builds on Dr Thomas's wider research in modelling for global public health, spanning air pollution, environmental exposure assessment and environmental epidemiology. Previous iterations of DIMAQ highlighted that half of global population were experiencing increasing . Other works include to provide a more realistic assessment of exposure to air pollutions as we interact with the environment. His research aims to help provide the evidence needed to support public health policy and decision-making worldwide.

Read more on WHO's website:

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Tue, 30 Jun 2026 15:45:48 +0100 https://content.presspage.com/uploads/1369/e2d0267e-9062-4a72-98f7-f6f7265de8ba/500_threechildrenskippingrope.creditpoco_bw.jpg?10000 https://content.presspage.com/uploads/1369/e2d0267e-9062-4a72-98f7-f6f7265de8ba/threechildrenskippingrope.creditpoco_bw.jpg?10000
Scientists directly observe elusive thorium–thorium bonding using Hirshfeld atom refinement /about/news/scientists-directly-observe-elusive-thoriumthorium-bonding-using-hirshfeld-atom-refinement/ /about/news/scientists-directly-observe-elusive-thoriumthorium-bonding-using-hirshfeld-atom-refinement/759036Journal: Chem

Full title: Actinide‑actinide bonding visualized by Hirshfeld atom refinement

DOI:10.1016/j.chempr.2026.103107

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Researchers have directly visualised thorium–thorium bonding using Hirshfeld atom refinement, providing experimental evidence of how these atoms share electrons in systems where this has been difficult to prove. 

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Researchers have directly visualised a rare type of chemical bond between some of the heaviest elements in the periodic table, providing experimental evidence of how these atoms share electrons in systems where this has been difficult to prove. 

In the study published in , researchers applied a method called Hirshfeld atom refinement, or HAR, to two model systems containing three closely spaced thorium atoms. These clusters display what the authors describe as multi‑centre thorium–thorium bonding, meaning electrons are shared across three atoms at once rather than between just two. 

By applying HAR the team demonstrated that experimental electron density measurements closely matched theoretical calculations, providing direct evidence of thorium–thorium bonding that had previously been predicted but never observed.

Chemical bonding is often described in terms of covalency, where atoms share electrons. While this concept is well understood, experimentally measuring covalency remains challenging and no single method works reliably in all cases. One of the most direct approaches is X‑ray charge density determination, which maps where electrons sit within a material, but this typically requires exceptionally high‑quality crystals and highly controlled conditions, limiting its use in routine studies.   

To address this, the researchers used HAR, a form of quantum crystallography, which combines experimental X‑ray data with theoretical calculations to build a detailed picture of electron density, the distribution of electrons that defines how atoms bond. This method is more accessible than traditional charge density techniques, but until now has been difficult to apply to heavy elements such as actinides, where electron behaviour becomes more complex due to relativistic effects.  

To test the method, the team analysed two trithorium clusters, which differ in how many electrons are involved in bonding. In one case, a single electron is shared across all three atoms, while in the other, two electrons are shared. Both systems act as “extreme test cases” because the atoms are heavy and closely spaced, making their electron distributions difficult to resolve.  

By analysing the electron density, the researchers identified features such as bond critical points, which mark where bonding interactions occur. The measurements matched closely with theoretical calculations, providing direct evidence for thorium–thorium bonding and helping resolve debate about how electrons are shared in these systems.  

The results also revealed clear differences between the two clusters, consistent with their underlying characteristics. These differences reflect how the number of shared electrons changes the nature of the bonding. Importantly, the method achieved this using standard experimental data rather than the specialised conditions typically required for charge density studies. This suggests that HAR could be applied more widely to investigate bonding in other complex materials. 

, adds: “Understanding how electrons are distributed in these systems is important because small changes in bonding can affect how materials behave, including their chemical reactivity and physical properties. By providing a way to directly measure electron sharing, the approach offers a more reliable way to connect experimental observations with theoretical predictions.” 

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Fri, 26 Jun 2026 16:41:10 +0100 https://content.presspage.com/uploads/1369/892d100b-3078-4848-9084-b2cc173c3568/500_thisimageshowsexperimental2ddeformationduringvisualiationandconfirmationofmulti-centreactinide-actinidebonding.jpg?10000 https://content.presspage.com/uploads/1369/892d100b-3078-4848-9084-b2cc173c3568/thisimageshowsexperimental2ddeformationduringvisualiationandconfirmationofmulti-centreactinide-actinidebonding.jpg?10000
£1.9 million fellowship to scale up next-generation 2D materials technologies /about/news/19-million-fellowship-to-scale-up-next-generation-2d-materials-technologies/ /about/news/19-million-fellowship-to-scale-up-next-generation-2d-materials-technologies/761549A researcher at The University of Manchester has been awarded a £1.9 million EPSRC Open Fellowship to develop new approaches for scaling up advanced 2D materials technologies for future electronic and quantum devices.

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A researcher at The University of Manchester has been awarded a £1.9 million EPSRC Open Fellowship to develop new approaches for scaling up advanced 2D materials technologies for future electronic and quantum devices. 

, based in the Department of Physics and Astronomy and the (NGI), will lead the five-year project “Future van der Waals Nanotechnologies”. The programme focuses on establishing new capabilities for producing high-quality 2D material heterostructures at wafer scale, supporting applications in electronics, quantum technologies and telecommunications. 

While van der Waals heterostructures can be engineered with high precision, most work to date has been limited to micrometre-scale samples. The project will address this by developing fabrication methods that operate at millimetre and wafer scales, enabling more consistent device performance and compatibility with industrial processes. 

Central to the programme is the development of a new platform designed to eliminate contamination between layers during assembly. This builds on recent advances from Professor Gorbachev’s group, including the creation of ultra-clean heterostructures using bespoke instrumentation. 

The fellowship will also establish a UK-based “2D Material Electronics” hub, providing access to advanced fabrication capabilities for academic and industrial users. By linking materials growth with device development, the initiative aims to accelerate progress in areas such as low-power electronics, neuromorphic computing and quantum technologies. 

This project builds on sustained research in this space. Some recent papers from the group include studies published in journals such as NatureScienceNature Nanotechnology and Nature Electronics, reflecting ongoing work on nanofabrication, electronic and optical properties of 2D materials, and their integration into device architectures. 

Professor Gorbachev has 20 years experience in graphene and 2D materials research, with over 100 peer-reviewed publications and a track record of developing new experimental approaches for nanofabrication and characterisation. His work has contributed to instrumentation and techniques now used by research groups internationally.  

The project will support a multidisciplinary team of researchers and technical specialists, alongside collaborations with partners across the UK and internationally. By developing scalable fabrication methods and strengthening links between fundamental research and application, the programme aims to support the next phase of 2D materials development and their translation into emerging technologies.

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Fri, 26 Jun 2026 16:24:08 +0100 https://content.presspage.com/uploads/1369/c6737f65-4892-481a-8045-f0b28d6a5791/500_campus-gilbert-square-1.jpg?10000 https://content.presspage.com/uploads/1369/c6737f65-4892-481a-8045-f0b28d6a5791/campus-gilbert-square-1.jpg?10000
The University of Manchester scientist honoured with prestigious Royal Society of Chemistry Prize /about/news/the-university-of-manchester-scientist-honoured-with-prestigious-royal-society-of-chemistry-prize/ /about/news/the-university-of-manchester-scientist-honoured-with-prestigious-royal-society-of-chemistry-prize/761528A scientist from The University of Manchester, has been named winner of the Royal Society of Chemistry’s Harrison-Meldola Early Career Prize.

Dr Conrad Goodwin was awarded the prize for the development of innovative methods in synthetic rare earth and actinide chemistry.

The modern world depends on controlling the movement of electrons. Batteries work by moving charge between materials, while many technologies rely on metals whose properties change when electrons are added or removed. Rare-earth elements are especially important: they are essential components of the compact, powerful magnets used in electric motors, wind turbines, speakers, and many other technologies. Yet the chemistry of rare-earth elements in unusual ‘charged’ states, where they hold more or fewer electrons than usual, remains difficult to study.

Dr Goodwin's work develops molecules that allow scientists to stabilise and understand these unusual states. Some of these molecules also show properties relevant to future quantum technologies, where individual molecules could be used to store or process information.

On receiving the prize, Dr Goodwin said: “It makes me very proud to see that the research my team is doing has been recognised at this level by members of our community, and I’m really honoured to be part of it.”

The Harrison-Meldola Early Career Prize for Chemistry is one of the Royal Society of Chemistry’s Research & Innovation Prizes, given in celebration of exceptional people advancing the chemical sciences across industry and academia.

Dr Helen Pain, CEO of the Royal Society of Chemistry, said: “Chemistry and chemists are everywhere in daily life and in our society, and our prizes reflect that depth and diversity. Our Research & Innovation prize winners include teams and individuals, professors and apprentices, as well as people from all around the world and in a wide range of roles and sectors. Each person’s contribution plays a vital role in advancing human knowledge and bettering the world that we all live in.

“I extend my warmest congratulations to Harrison-Meldola Early Career Prize for Chemistry. Winning an RSC Prize is a remarkable achievement. You join the ranks of a star-studded roster stretching back over 150 years, including several dozen who went on to win Nobel Prizes. Our winners are exceptional role models for our communities, and we’re so pleased to be celebrating such an extraordinary cohort this year.”

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Concrete waste from nuclear sites could help lock away radioactive strontium for the long term /about/news/concrete-waste-from-nuclear-sites-could-help-lock-away-radioactive-strontium-for-the-long-term/ /about/news/concrete-waste-from-nuclear-sites-could-help-lock-away-radioactive-strontium-for-the-long-term/761452Journal: ACS ES&T Water  

Full title: Strontium Interactions with Crushed Concrete Waste: Implications for Management of Radioactively Contaminated Land  

DOI: 10.1021/acsestwater.6c00365 

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New research shows concrete can react and become a long‑term sink for strontium-90, particularly when exposed to air or treated with phosphate. This means crushed concrete from legacy nuclear facilities could play a far greater role in safely managing radioactive land than previously understood. 

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Crushed concrete from legacy nuclear facilities could play a far greater role in safely managing radioactive land than previously understood. 

Research published in and conducted by scientists from The University of Manchester, United Kingdom National Nuclear Laboratory and Clemson University and funded by the Nuclear Decommissioning Authority, examined how crushed concrete interacts with strontium‑90, a mobile radioactive contaminant found at nuclear legacy sites such as Sellafield and Hanford. 

The team found that, under conditions similar to those expected in shallow, on‑site disposal environments, concrete can react and become a long‑term sink for strontium-90, particularly when exposed to air or treated with phosphate. 

The research team used concrete sourced from the UK’s Nuclear Decommissioning Authority and tested how it behaved when mixed with synthetic groundwater containing either stable strontium or trace levels of radioactive strontium‑90. Experiments ran for three months under two contrasting conditions: air‑limited, representing sealed or low‑oxygen (sub-surface) environments, and air‑equilibrated (air-exposed), representing disposal scenarios where air is present. 

In air‑equilibrated systems, the crushed concrete removed around 82% of strontium from solution within three months, compared with only 14% under air‑limited conditions. This difference was linked to the formation of calcite, a calcium carbonate mineral that forms as concrete reacts with carbon dioxide in air. Strontium can substitute for calcium in calcite, locking it into the mineral structure. 

X‑ray absorption spectroscopy confirmed that strontium was partially incorporated into newly formed calcite in these air‑exposed systems, providing a mechanism for long‑term removal of strontium-90 from groundwaters. 

The team also tested two phosphate treatments – one where phosphate was added during the experiment, and one where the concrete was pre‑treated with phosphate. Both approaches increased strontium uptake, even when air was limited. 

In air‑equilibrated phosphate systems, up to 98% of strontium was removed from solution within 48 hours. Microscopy showed that poorly crystalline calcium phosphate coatings formed on the concrete surface, providing additional sites for strontium to sorb or incorporate over long timescales to allow radioactive decay to stable Zr. 

Strontium‑90 is a key contaminant at many historic nuclear sites because it is relatively mobile in groundwater. Significant volumes of lightly contaminated concrete are generated during decommissioning, and on‑site disposal is increasingly being explored to manage this material. 

The findings suggest that, when concrete is crushed and exposed to air – as would occur during recycling or shallow burial – natural carbonation processes can significantly enhance strontium retention. Phosphate treatments could further improve performance, particularly in areas where air access is limited. 

added: “These results give us a clearer picture of what happens when concrete waste interacts with groundwater over time. By understanding the mechanisms that trap strontium, we can better support safe, evidence‑based decisions about on‑site disposal and long‑term radioactively contaminated land management.”

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Thu, 25 Jun 2026 20:00:16 +0100 https://content.presspage.com/uploads/1369/84e35fcf-e29d-44bf-b9d4-638625960fb7/500_scientistsfromtheuniversityofmanchesterexamininghowcrushedconcreteinteractswithstrontium90amobileradioactivecontaminantfoundatnuclearlegacysitessuchassellafieldandhanford..jpg?10000 https://content.presspage.com/uploads/1369/84e35fcf-e29d-44bf-b9d4-638625960fb7/scientistsfromtheuniversityofmanchesterexamininghowcrushedconcreteinteractswithstrontium90amobileradioactivecontaminantfoundatnuclearlegacysitessuchassellafieldandhanford..jpg?10000
University of Manchester researcher secures ERC Advanced Grant for atomic-scale nanotechnology /about/news/university-of-manchester-researcher-secures-erc-advanced-grant-for-atomic-scale-nanotechnology/ /about/news/university-of-manchester-researcher-secures-erc-advanced-grant-for-atomic-scale-nanotechnology/758984A researcher at The University of Manchester has been awarded a prestigious £3m to develop new ways of controlling matter at the atomic scale.

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A researcher at The University of Manchester has been awarded a prestigious to develop new ways of controlling matter at the atomic scale.

Roman Gorbachev

, based in the Department of Physics and Astronomy and the (NGI), will lead the £3m five-year project Van der Waals Nanomachines (ATOMSTEP). The ERC Advanced Grant scheme is among the most competitive in Europe, supporting established researchers to pursue ambitious, curiosity-driven science.

Professor Gorbachev said: "This project aims to establish a new approach to controlling motion at the nanoscale using two-dimensional materials. By developing electrically driven nanomachines, we will be able to study and assemble atomic-scale systems in ways that are not currently possible."

The project will combine atomically thin materials into engineered structures, van der Waals heterostructures, whose electronic and mechanical properties can be precisely controlled. From these, the team will build a new class of on-chip nanomachines that move in controlled, atomic-scale steps, able to move and position atomic-scale objects with high precision. The work brings together the fundamental behaviour of layered materials, the design and construction of the nanomachines themselves, and their use in emerging technologies, including quantum devices.

The research will be carried out at the NGI, which provides for nanofabrication and advanced characterisation. It builds on the group's recent work on ultra-clean fabrication of van der Waals heterostructures and atomic-scale imaging, published in journals including , and , and further strengthens Manchester's position as a centre for advanced materials science.

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Wed, 24 Jun 2026 15:07:08 +0100 https://content.presspage.com/uploads/1369/c6737f65-4892-481a-8045-f0b28d6a5791/500_campus-gilbert-square-1.jpg?10000 https://content.presspage.com/uploads/1369/c6737f65-4892-481a-8045-f0b28d6a5791/campus-gilbert-square-1.jpg?10000
Plasma approach keeps catalysts working for longer in hydrogen production /about/news/plasma-approach-keeps-catalysts-working-for-longer-in-hydrogen-production/ /about/news/plasma-approach-keeps-catalysts-working-for-longer-in-hydrogen-production/758967Journal: ACS Catalysis

Full title: Enhanced time-on-stream stability of Pt/CeO2 catalysts for the water gas shift reaction under non-thermal plasma activation

DOI:10.1021/acscatal.6c02042

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Manchester scientists have shown how a plasma-based approach, using non thermal plasma can prevent catalyst deactivation in a key hydrogen production reaction, maintaining stable performance for 30 hours.

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Scientists from The University of Manchester have shown how a plasma-based approach, using non thermal plasma - an electrically energised gas often described as the fourth state of matter - can prevent catalyst deactivation in a key hydrogen production reaction, maintaining stable performance for 30 hours while also changing how the reaction proceeds at the molecular level. 

The study published in focuses on the water gas shift reaction. This is a widely used process for producing and purifying hydrogen, which is expected to play an important role in future low carbon energy systems. 

Using a 2.0% Pt/CeO₂ catalyst, researchers found that carbon monoxide conversion dropped from 34.3% to 21.5% under conventional thermal operation. When non thermal plasma was applied, conversion remained stable at around 34.1% over the full 30 hour test. 

The researchers linked the performance difference to changes in surface processes on the catalyst. Under thermal conditions, carbon-containing species and strongly adsorbed carbon monoxide gradually build up, blocking the active sites needed for the reaction and reducing performance. This process, known as carbon monoxide poisoning, is a major limitation for platinum-based catalysts. 

In contrast, plasma generates highly reactive species that continuously convert or remove these surface deposits before they can accumulate. This keeps the catalyst surface dynamic and preserves the active sites required for the reaction. Importantly, these effects occur at relatively low temperatures where conventional catalysts struggle to perform efficiently. 

Using in situ spectroscopy, the researchers tracked how molecules behaved on the catalyst surface during operation. Under thermal conditions, carbon-rich intermediates steadily accumulated over time, directly correlating with the observed drop in activity. Under plasma activation, these species were present in much lower amounts or behaved as weakly bound species that did not interfere with the reaction. 

The study also shows that plasma changes how the reaction proceeds. Under thermal conditions, the reaction mainly follows a pathway involving formate intermediates, which tend to build up on the catalyst surface and contribute to deactivation. Under plasma conditions, the reaction shifts to a different route involving carboxyl intermediates, which turn over more quickly and do not accumulate. 

This shift in mechanism helps explain why performance remains stable. Plasma also reduces the inhibitory effect of carbon monoxide, meaning more active sites remain available even under conditions where conventional systems become limited. 

Maintaining catalyst stability is important for industrial processes because deactivation leads to reduced efficiency, shutdowns and the need for regeneration or replacement. In this study, regeneration under thermal conditions only partially restored performance, and activity declined again during subsequent operation. 

The findings suggest that integrating plasma activation into catalytic systems could offer a practical route to improving the durability and efficiency of hydrogen production by the water gas shift processes. By preventing catalyst deactivation and maintaining stable performance over time, this approach could improve reliability and reduce operational demands in industrial settings. 

Dr Chawdhury adds: “Understanding the mechanism behind this effect gives us new opportunities to design more durable catalysts for future hydrogen production processes, which also provides valuable guidance for industrial research and development.” 
 

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Wed, 24 Jun 2026 12:57:04 +0100 https://content.presspage.com/uploads/1369/43e6d0b7-891e-4f0f-bb95-ac933f916d04/500_enhancedtime-on-streamstabilityofptceo2catalystsforthewatergasshiftreactionundernon-thermalplasmaactivationf.png?10000 https://content.presspage.com/uploads/1369/43e6d0b7-891e-4f0f-bb95-ac933f916d04/enhancedtime-on-streamstabilityofptceo2catalystsforthewatergasshiftreactionundernon-thermalplasmaactivationf.png?10000
Manchester researcher helps capture most detailed picture of the Milky Way’s crowded heart /about/news/manchester-researcher-helps-capture-most-detailed-picture-of-the-milky-ways-crowded-heart/ /about/news/manchester-researcher-helps-capture-most-detailed-picture-of-the-milky-ways-crowded-heart/758937Researchers at The University of Manchester have played a key role in a new scientific release from the European Space Agency’s Euclid mission, unveiling the most detailed photo ever made of our Milky Way galaxy’s centre in visible light.

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Researchers at The University of Manchester have played a key role in a new scientific release from the European Space Agency’s Euclid mission, unveiling the most detailed photo ever made of our Milky Way galaxy’s centre in visible light.

The image, which contains more than 60 million stars, offers scientists an unprecedented view of the galactic bulge – the dense, bright heart of our Galaxy – and could help researchers confirm the existence of any exoplanet found in this region and measure their mass.

The new data comes from the Euclid Galactic Bulge Survey, a dedicated observing programme designed to support the discovery and study of exoplanets using a technique known as microlensing.

Captured over around 26 hours on 23 March 2025, the Euclid space telescope covered nine neighbouring fields of view, .  The result reveals a region of sky packed with stars, nebulas and star clusters in extraordinary detail.

, Astrophysicist at The University of Manchester, said: “Opening Euclid’s eyes towards the centre of our Galaxy was a very exciting moment for the team. It was the culmination of years of preparation and simulations to ensure Euclid could observe such a crowded region of the sky successfully, and without impacting on Euclid’s main science goals. The view Euclid gives us of the Galactic Centre region is absolutely stunning.”

The new observations show how Euclid’s capabilities can also be used for a broad range of astrophysics.

In this case, researchers are using the mission’s exceptionally sharp visible-light observations to identify the host stars to planets that cause microlensing events. Microlensing occurs when a foreground planetary system passes in front of a distant background star, briefly magnifying its light.

Dr Kerins co-led the Euclid Exoplanet Science Working Group between 2023 and 2025 and helped lead the effort to secure approval for the Galactic Bulge Survey, shape how it would be carried out, and help coordinate its successful execution.

The work required significant innovation, as Euclid was not originally designed to observe such a densely crowded region of the sky. Dr Kerins worked closely with colleagues within the Euclid Exoplanet Science Working Group, as well as the Euclid Project Scientists, instrument teams and spacecraft operations teams across the Euclid Consortium. He also helped to press the science case to Euclid colleagues and to ESA and international partners involved in Euclid. Extensive simulations and technical studies were undertaken to ensure the spacecraft could operate effectively in these conditions without affecting its core mission to study dark matter and dark energy.

The Euclid Galactic Bulge Survey targets regions rich in past microlensing events observed from the ground, where the lens and source have since begun to separate.

“This time baseline makes it possible to track the motion of the host stars and better characterise the planetary systems, ultimately enabling more accurate mass estimates for planets as small as Mars,” says Dr Kerins.

Because the centre of the Milky Way is so densely populated with stars, it provides one of the best places in the sky to look for these events. “Towards the centre of the galaxy, there is one chance in a million for a star to be magnified, while it would be one in a billion on other lines of sight.” states Matthew Penny, Assistant professor at Louisiana State University and current lead of the Euclid Exoplanets team. Dr Penny is a Manchester Physics undergraduate and postgraduate alumnus.

The survey is expected to help scientists better characterise known planetary systems and prepare for future discoveries. In particular, the Euclid data will provide an important reference point for observations to be made by NASA’s upcoming Nancy Grace Roman Space Telescope, which will repeatedly observe the same region of the sky as part of its own microlensing and transit planet-hunting programmes.

Roman has recently arrived at the Kennedy Space Centre and is due to launch on August 30th this year. The European Space Agency is a partner in Roman and Dr Kerins is the ESA-appointed scientist to the Roman Galactic Bulge Time Domain Survey. Dr Kerins leads the exoplanet demographics working group within the transit science team that is expecting Roman to discover around 100,000 exoplanets across the Galaxy. 

By comparing Euclid’s earlier images with future exoplanet detections from Roman, researchers expect to be able to confirm transiting planets more robustly and determine the masses of microlensing planets with greater precision.

Dr Kerins adds: “We are at the dawn of an exciting new age of exoplanet discovery, and Euclid has just fired the starting pistol”.

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Wed, 24 Jun 2026 12:03:36 +0100 https://content.presspage.com/uploads/1369/c3282beb-3350-466c-b847-0e28aa08f7b0/500_galactic_bulge_survey_area_4.8deg2.jpg?10000 https://content.presspage.com/uploads/1369/c3282beb-3350-466c-b847-0e28aa08f7b0/galactic_bulge_survey_area_4.8deg2.jpg?10000
Manchester scientists design ‘tunable’ biomolecules to probe how sugars behave /about/news/tunable-biomolecules-to-probe-how-sugars-behave/ /about/news/tunable-biomolecules-to-probe-how-sugars-behave/758004Researchers at Manchester Institute of Biotechnology have developed a new way to precisely build and modify complex sugar molecules, creating powerful tools to study how they function in biology and disease.Researchers at the have developed a new way to precisely build and modify complex sugar molecules, creating powerful tools to study how they function in biology and disease.

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Sugars are not just a source of energy – they also play a crucial role in how cells communicate, how proteins interact and how materials behave in medicine and industry. But studying these processes is challenging because sugar molecules are structurally complex and difficult to control.

In a new study published in , the team – led by – have created modified sugar building blocks that can be assembled automatically into defined structures, enabling scientists to probe their behaviour in unprecedented detail.

The team focused on alginates – a sugar widely used as a thickener in food and as a components of wound dressings. By introducing a small chemical modification (replacing part of the molecule with fluorine), they were able to subtly alter how these sugars behave without disrupting their overall structure.

Crucially, the researchers showed that these modified building blocks can be assembled using automated synthesis – a process that allows complex molecules to be built step by step with high precision. This enabled the creation of a library of tailored sugar chains with specific modifications at defined positions.

Unlocking how structure controls function

Using advanced analytical techniques, including nuclear magnetic resonance (NMR), the team demonstrated that the modified sugars retain their overall shape, even though key internal interactions are altered.

This finding is significant because it shows that scientists can “tune” specific features of a molecule without fundamentally changing how it behaves – allowing them to isolate and study individual interactions in complex biological systems.

New tools for biotechnology and medicine

The ability to design and synthesise these molecules opens up new possibilities for research and application.

Fluorinated sugars can act as sensitive “reporters”, making it easier to track interactions between molecules using spectroscopic methods. They can also help scientists better understand how enzymes process sugars – an important step in areas ranging from infection biology to materials science.

More broadly, this work lays the foundation for developing tailored carbohydrate-based materials, where structure and function can be engineered with precision.

By providing a reliable method to build and study these modified sugars, the research offers a new platform for exploring how carbohydrate structure affects behaviour – helping to bridge a long-standing gap in molecular science.

This research was published in: Angewandte Chemie - International Edition

Full title of the paper: 3-Deoxy-3-Fluoro Mannuronic Acid Alginates: Stereoselective Automated Synthesis and Conformational Behaviour

DOI: 10.1002/anie.5914227

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Wed, 24 Jun 2026 09:30:00 +0100 https://content.presspage.com/uploads/1369/505cf6a1-5d0a-4ccd-8f48-35907cf307ab/500_sugarmolecule_1920x647.jpg?10000 https://content.presspage.com/uploads/1369/505cf6a1-5d0a-4ccd-8f48-35907cf307ab/sugarmolecule_1920x647.jpg?10000
Real-time microscopy reveals how semiconductor nanowires grow, and how bismuth seeds can speed their formation /about/news/real-time-microscopy-reveals-how-semiconductor-nanowires-grow-and-how-bismuth-seeds-can-speed-their-formation/ /about/news/real-time-microscopy-reveals-how-semiconductor-nanowires-grow-and-how-bismuth-seeds-can-speed-their-formation/757703This research was published in the journal Matter.

In situ liquid-phase TEM electrodeposition of tellurium nanostructures

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Scientists from the at The University of Manchester and Sun Yat-sen University, have captured the growth of semiconducting tellurium nanostructures in liquid in real time, revealing how tiny seed particles form, grow into nanowires and compete for material as the structures develop. The study, published in , also shows that adding bismuth seed particles can make tellurium easier to deposit under specific electrodeposition conditions used in the experiments.

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Scientists from the at The University of Manchester and Sun Yat-sen University, have captured the growth of semiconducting tellurium nanostructures in liquid in real time, revealing how tiny seed particles form, grow into nanowires and compete for material as the structures develop. The study, published in , also shows that adding bismuth seed particles can make tellurium easier to deposit under specific electrodeposition conditions used in the experiments.

The work focuses on tellurium, a semiconductor of interest for electronic, thermoelectric and optoelectronic applications, where performance depends strongly on the size and shape of the nanostructures produced. Although liquid-phase synthesis is a scalable and relatively low-cost way to make these materials, it has been difficult to observe exactly how anisotropic tellurium structures begin to form and evolve during growth.

Using liquid-phase transmission electron microscopy, the researchers tracked the early stages of tellurium formation at the nanoscale. They found that tellurium first appears as spherical seed particles, which then give rise to multiple nanowires. During growth, nearby wires compete for available material, affecting local growth speed and branching. Across the experiments, local nanowire growth rates were measured in the range of 1 to 15 nm per second, depending on electron flux and the presence of neighbouring structures.

, corresponding author at The University of Manchester and the National Graphene Institute, said: “This study lets us see, in real time, how tellurium nanowires emerge and evolve in liquid. By directly observing nucleation, growth and branching at the nanoscale, we can begin to understand how to control these processes much more precisely. That matters because the performance of tellurium-based materials depends strongly on their size and shape.”

A second key finding was that bismuth seed nanoparticles dramatically change how tellurium grows. In the microscopy experiments, bismuth increased the number of nucleation sites and promoted more highly branched, fern-like structures. Follow-up electrodeposition experiments confirmed that bismuth also lowers the reducing potential needed for tellurium deposition and can substantially increase the amount of tellurium deposited under the same conditions. Together, these results show how insights from real-time microscopy can guide more effective materials synthesis outside the microscope.

Dr Yi-Chao Zou, co-corresponding author, said: “One of the most exciting aspects of this work is that the behaviour we observed in the liquid cell translated into conventional electrodeposition experiments. We found that bismuth seeding not only promotes tellurium nucleation but also makes deposition easier and more productive at a fixed potential. That opens up new possibilities for designing tellurium nanostructures with tailored morphologies for future device applications.”

The study, a collaboration between Sun Yat-sen University, The University of Manchester, the National Graphene Institute and Beijing Institute of Technology, suggests that real-time microscopy can do more than describe nanostructure growth. In this case, it identified a specific way to alter nucleation behaviour and improve deposition under defined experimental conditions. That could help researchers refine how tellurium nanostructures are produced for device-relevant studies, while keeping claims closely tied to the systems tested here.  The team report the findings could help accelerate the optimisation of low-dimensional nanostructures for electronics, energy conversion and sensing applications.

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Thu, 18 Jun 2026 16:00:00 +0100 https://content.presspage.com/uploads/1369/0851b904-ac36-456d-83e8-22542752c931/500_matterpaperimage.png?10000 https://content.presspage.com/uploads/1369/0851b904-ac36-456d-83e8-22542752c931/matterpaperimage.png?10000
Electrical control of spin signals demonstrated in graphene superlattices /about/news/electrical-control-of-spin-signals-demonstrated-in-graphene-superlattices/ /about/news/electrical-control-of-spin-signals-demonstrated-in-graphene-superlattices/757826This research was published in the journal Nature Communications.

Spin magnetic proximity effect in graphene superlattices

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Researchers at the , in collaboration with the National University of Singapore, have shown that the magnetic behaviour of electrons in graphene can be precisely controlled using electricity, revealing unusually large spin signals in a carefully engineered graphene system. 

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Researchers at the , in collaboration with the National University of Singapore, have shown that the magnetic behaviour of electrons in graphene can be precisely controlled using electricity, revealing unusually large spin signals in a carefully engineered graphene system. 

The study, published in , demonstrates how placing graphene close to a magnetic material can influence the spin of electrons without permanently altering graphene itself. By combining this magnetic proximity effect with graphene superlattices and operating at very low charge densities, the researchers were able to strongly tune how spins move through the material. 

“This work shows that by combining graphene with nearby magnetic materials, we can gain a high level of control over electron spin using electrical signals alone,” said Dr Daniel Burrow, from The University of Manchester. “In simple terms, we are learning how to pass information through graphene using the spin of electrons rather than their electrical charge.” 

Electron spin is a quantum property that can act like a tiny magnetic compass needle. While conventional electronics rely on the movement of charge, spin-based approaches aim to use this magnetic degree of freedom to process and carry information, potentially reducing energy losses. 

In the study, the team used cobalt contacts to induce magnetism in graphene through proximity, meaning the graphene itself does not become magnetic. They then injected and detected pure spin currents, allowing them to probe how spin transport changes across different electronic regimes. 

Near the charge neutrality point, where graphene has very few mobile charge carriers, the researchers observed a clear reversal of the spin signal. This behaviour indicates that the magnetic proximity effect creates a spin dependent energy splitting in graphene, which governs how spins travel through the material. 

Importantly, the same effect was also observed at additional neutrality points that appear when graphene is precisely aligned with hexagonal boron nitride. These so called superlattice features show that proximity induced spin control applies not only to graphene’s original electronic bands but also to those reconstructed by the superlattice structure. 

“Our measurements show that the same underlying mechanism controls spin transport across all these regimes,” said Dr Burrow. “That tells us we are seeing a robust physical effect rather than something specific to a single device setting.”

The strongest signals were observed in a bilayer graphene superlattice device designed to open an energy gap in the electronic structure. In this specific system, the researchers measured spin polarisations approaching 50 per cent and nonlocal spin resistances exceeding 300 ohms. These values are nearly two orders of magnitude larger than those measured away from charge neutrality in the same experimental platform. 

The study shows that low carrier density, combined with magnetic proximity effects and engineered band structure, can greatly enhance spin filtering and detection. While the work focuses on demonstrating the physics, the authors note that electrical control of spin at low power could be relevant for future spin based electronic technologies. 

“This research shows that we can engineer graphene systems where spin signals become both large and electrically tunable,” said , a co-author of the study. “That opens up new ways to explore spin transport in two-dimensional materials and brings us closer to using these effects in practical devices.” 

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Thu, 18 Jun 2026 14:12:08 +0100 https://content.presspage.com/uploads/1369/3fc9f8c5-1882-49d3-8748-11f232a3baf7/500_001spi~1.png?10000 https://content.presspage.com/uploads/1369/3fc9f8c5-1882-49d3-8748-11f232a3baf7/001spi~1.png?10000
University of Manchester researchers recognised with Royal Society of Chemistry Horizon Prize /about/news/university-of-manchester-researchers-recognised-with-royal-society-of-chemistry-horizon-prize/ /about/news/university-of-manchester-researchers-recognised-with-royal-society-of-chemistry-horizon-prize/758422Researchers from The University of Manchester have been recognised as part of an international team awarded a Royal Society of Chemistry (RSC) Horizon Prize for advances in solid-state battery technology. 

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Researchers from The University of Manchester have been recognised as part of an international team awarded a Royal Society of Chemistry (RSC) Horizon Prize for advances in solid-state battery technology. 

The team, , received the Stephanie L Kwolek Prize for developing a scalable solid-state lithium metal battery architecture that integrates nanocarbon-enhanced cathodes with solid electrolytes.

The award recognises a collaboration between researchers at PETRONAS, The University of Manchester, and Deakin University in Melbourne. Their work focuses on overcoming key barriers to the commercialisation of solid-state lithium metal batteries, including improving energy density, safety and manufacturability. 

Solid-state batteries replace the liquid electrolyte found in conventional lithium-ion batteries with a solid alternative, offering potential advantages in stability and performance. However, challenges remain in ensuring reliable operation at scale. The team’s approach combines nanocarbon-enhanced cathodes with solid electrolytes to deliver a design that can be manufactured using processes compatible with industry. 

The RSC Horizon Prizes, introduced in 2020, recognise teams working on innovative projects at the frontiers of the chemical sciences. The prizes highlight collaborative research that addresses global challenges and demonstrates significant progress towards practical applications.

Dr Helen Pain, Chief Executive of the Royal Society of Chemistry, said: “The purpose of the Horizon Prizes is to recognise those who are pioneering new techniques, technologies and discoveries. Our winners demonstrate how expertise from across chemistry and related disciplines can be brought together to tackle some of the most pressing global challenges.” 

The Manchester researchers contributed expertise in nanomaterials and their integration into functional devices, building on the University’s strengths in advanced materials and energy research. Their involvement in the project reflects ongoing collaborations with international partners and industry to accelerate the development of next-generation technologies. 

The prize is one of a number of Horizon Prizes awarded this year by the RSC, which form part of a wider programme recognising excellence in research, innovation and education across the chemical sciences. 

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Thu, 18 Jun 2026 12:23:41 +0100 https://content.presspage.com/uploads/1369/856fc75b-edb1-409f-973e-b3c18e8a8594/500_markandian.png?10000 https://content.presspage.com/uploads/1369/856fc75b-edb1-409f-973e-b3c18e8a8594/markandian.png?10000
More than one million pupils worldwide share their scientific curiosity through Great Science Share for Schools /about/news/more-than-one-million-pupils-worldwide-share-their-scientific-curiosity-through-great-science-share-for-schools/ /about/news/more-than-one-million-pupils-worldwide-share-their-scientific-curiosity-through-great-science-share-for-schools/758116More than one million pupils from 58 countries have been asking, investigating and sharing the scientific questions that matter to them through The University of Manchester’s Great Science Share for Schools campaign.

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More than one million pupils from 58 countries have been asking, investigating and sharing the scientific questions that matter to them through The University of Manchester’s Great Science Share for Schools campaign.

The milestone marks the largest level of participation in the campaign's history, having launched in 2016. This demonstrates the growing global appetite for teachers to upskill in how to engage 5–14-year-olds in practical science learning in schools.

Teachers and their pupils have been involved in thinking about scientific questions that interest them. Time has been dedicated to encouraging them to plan and undertake investigations, gathering evidence and drawing conclusions on topics ranging from nature, weather, motion and materials.

Under the annual theme 'Globally Curious', the pupils’ questions have demonstrated creativity, curiosity and wonder.

  • Which is the smallest animal that makes the biggest difference in our environment?
  • What do ants like to eat the most?
  • How does friction affect the distance a car travels?
  • How do different exercises affect your heart rate?
  • How do my clothes shed microfibres and does it matter?

Teachers and educators across the globe get involved in many ways. As an inclusive campaign, sharing events take place in schools, gardens, zoos, hospital schools and community spaces.  This year saw the campaign expand its reach into Slovenia and Spain, with bespoke training for teachers and translated materials that increasingly support engagement globally.

Brompton-Westbook Primary in Kent was the school that took registrations beyond the million mark. Claire Hofer, the school’s Science Lead, said Great Science Share for Schools has enabled their pupils and teachers to do more enquiry-based science, which they share with other pupils at a showcase event at the Discovery Park in Sandwich.

Similarly, The University of Manchester welcomed 31 schools from across Greater Manchester to its Nancy Rothwell Building for a large in-person event, where pupils showcased their investigations and discoveries with the Lord Mayor encouraging them on.

The Great Science Share for Schools campaign was founded by Professor Lynne Bianchi, Vice Dean for Social Responsibility at The University of Manchester, to elevate the prominence of science in the classroom through learner-led enquiry, inclusive participation and collaboration.

Professor Bianchi said: “2026 is a truly great year for GSSfS by reaching this huge milestone. This makes a huge difference to teachers and young people, as well as showing that there is keen interest to raise the profile of science education for all. As the University’s From Manchester for the world 2035 strategy really takes pace, GSSfS models our values towards social responsibility and widening participation.”

Grace Marson, Campaign Manager for Great Science Share for Schools, added: “We are really proud that the campaign continues to grow as this means it is continuing to support teachers to upskill their own knowledge and develop pupils’ confidence in science enquiry.”

As participation surpasses one million pupils for the first time, the achievement comes amid a new Royal Society report, calling for stronger support for public engagement with science, technology, engineering and mathematics subjects, highlighting the growing importance of initiatives such as Great Science Share for Schools.

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Tue, 16 Jun 2026 08:41:42 +0100 https://content.presspage.com/uploads/1369/ba424452-6f4e-4ebe-b3b3-75f29d4e3a7e/500_a187e56b-27fe-4126-8c1d-f4fd74269b69.jpg?10000 https://content.presspage.com/uploads/1369/ba424452-6f4e-4ebe-b3b3-75f29d4e3a7e/a187e56b-27fe-4126-8c1d-f4fd74269b69.jpg?10000
Professor Steve Eichhorn announced as incoming Director of Royce Manchester /about/news/professor-steve-eichhorn-announced-as-incoming-director-of-royce-manchester/ /about/news/professor-steve-eichhorn-announced-as-incoming-director-of-royce-manchester/757940The University of Manchester is pleased to announce that Professor Steve Eichhorn FREng will take up the position of Director of the Henry Royce Institute at Manchester in November this year. 

This is a significant leadership role at the heart of both the University and Royce, the UK's national institute for advanced materials research and innovation. As the lead Partner and host of Royce, Manchester plays a pivotal role in shaping the UK's materials research and innovation landscape. 

As Director of Royce Manchester, Professor Eichhorn will provide strategic leadership across Royce activities in Manchester ensuring strong alignment with the national Institute while advancing the University's ambitions across the Faculty of Science and Engineering. 

Materials science and engineering are central to addressing some of the most pressing challenges facing society today, from clean energy and sustainability to advanced manufacturing, digital technologies and healthcare. 

Royce is accelerating the discovery, development and deployment of advanced materials to support a sustainable and prosperous UK. Manchester, as the hub of this national endeavour brings together world-class facilities, outstanding academic and technical expertise and strong partnerships with industry. 

Professor Eichhorn is an internationally recognised materials scientist whose research and leadership have made significant contributions to the field. He is an expert in cellulosic materials, natural fibre composites and biomimetic/functional materials. 

In his new role, he will work closely with the Royce CEO and Chief Scientific Officer, University and Faculty leadership and Royce Partners across the UK to ensure Royce Manchester continues to thrive as a cornerstone of the national materials innovation ecosystem. 
 

Welcoming the appointment, Professor Sarah Sharples, Vice-President and Dean of the Faculty of Science and Engineering and Member of the Royce Governing Board, said: 

“We know we are in a period of incredible societal change, and to rise to that moment, partnership sits at the heart of our mission – with universities, industry and government. We need to translate the incredible discoveries that emerge from scientists and engineers into impact and innovation. Steve’s appointment is extremely important. He brings an outstanding record of leadership with a strong commitment to values-led leadership within science and engineering nationally and internationally. His stewardship will further strengthen collaboration through Royce and ensure research from Manchester helps drives the UK’s ambitions for innovation-led growth and continues to deliver transformative impact at a global scale.”

Professor David Knowles, Royce CEO added: 

"Steve’s deep understanding of the advanced materials landscape alongside his long-standing commitment to the Royce mission as a former member of our Strategic Advisory Board (SAB) makes him exceptionally well placed to lead Royce Manchester through the next phase of its development. Manchester of course is at the heart of the Henry Royce Institute and plays a vital role in connecting world-leading research with regional industrial innovation and national priorities. I look forward to working closely with Steve as we continue to strengthen Royce's impact across the UK.”

 

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I am delighted to be taking up this position as the Director of the Henry Royce Institute at Manchester. The Institute at Manchester holds huge potential, and I relish the challenge in helping to make things happen. I look forward to working with colleagues to bring about real impact in the materials science that we can do at Manchester, and in collaboration with the whole of Royce, its national and international partners, and the local region. It is of course a return for me to Manchester and Materials Science, having left here in 2011. I am pleased to be back in the city where I was born, and subsequently raised academically!”&Բ;&Բ;ձ> Mon, 15 Jun 2026 09:26:55 +0100 https://content.presspage.com/uploads/1369/ccd54672-373f-4e42-ac4e-60605f19e892/500_steve-eichhorn.jpg?10000 https://content.presspage.com/uploads/1369/ccd54672-373f-4e42-ac4e-60605f19e892/steve-eichhorn.jpg?10000
Multinex: An ultra lightweight AI model advancing low light image enhancement /about/news/multinex-an-ultra-lightweight-ai-model-advancing-low-light-image-enhancement/ /about/news/multinex-an-ultra-lightweight-ai-model-advancing-low-light-image-enhancement/757239Full title: Multinex: Lightweight Low-light Image Enhancement via Multi-prior Retinex

Presented at the IEEE/CVF Conference on Computer Vision and Pattern Recognition 2026

DOI: arXiv:2604.10359

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A University of Manchester student has developed a powerful new ultra‑lightweight tool that can turn dark, noisy footage into clear, detailed and usable images.

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A University of Manchester student has developed a powerful new ultra‑lightweight tool that can turn dark, noisy footage into clear, detailed and usable images.

, a new model for low‑light image enhancement (LLIE), was created by Computer Science undergraduate Alexandru Brateanu during his third-year project, working with academic supervisors.

The model outperforms comparable compact systems, recovering detail and clarity from images that would previously have been considered unusable.

The advancement has significant implications for photography, security, and a wide range of computational imaging tasks.

Low‑light image enhancement seeks to restore natural visibility, colour fidelity, and structural detail in scenes captured under poor illumination. While recent LLIE models have achieved impressive results, many rely on heavy architectures with large parameter counts, resulting in high computational cost and limited real‑time applicability. Efficiency has therefore become a central research challenge: how to enhance images more effectively while dramatically reducing model size.

In the work presented at the IEEE/CVF Conference on Computer Vision and Pattern Recognition 2026, the team proposes a structured solution grounded in classical colour vision theory and implemented using modern neural components within the Retinex framework. Retinex, a foundational approach in image enhancement, decomposes an image into illumination (light) and reflectance (colour) components to better handle low‑light scenes.

The design motivation behind Multinex is to extract as much useful information as possible from low‑light images using a highly compact architecture. By prioritising enhancement over reconstruction and leveraging lightweight neural operations, Multinex achieves strong illumination correction, detail recovery, and colour fidelity while using only a fraction of the parameters required by existing approaches.

The model is released in both a lightweight version (45K parameters) and an extremely compact nano version (0.7K parameters), each offering substantial reductions in computational load. Comparison to corresponding lightweight models such as PairLIE (330K parameters) and ZeroDCE (80K parameters) Multinex shows a significant performance improvement.

Like other LLIE techniques, Multinex still faces challenges in scenes with severe spectral distortions, lens flares, or mixed artificial and natural lighting. The team aims to extend the framework to these complex cases, exploring alternative formulations such as tone‑mapping or multiplicative residuals, and applying Multinex principles to related domains including intrinsic image decomposition, colour constancy, underwater enhancement, and haze removal.

The researchers demonstrate that Multinex delivers state‑of‑the‑art performance at real‑time cost, highlighting the power of combining analytic priors with modern lightweight design.

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Mon, 08 Jun 2026 10:51:46 +0100 https://content.presspage.com/uploads/1369/c3713dde-b4e3-47d7-8be4-ad1f3f8c0cb2/500_examplediagram.credittingtingmutheuniversityofmanchester.png?10000 https://content.presspage.com/uploads/1369/c3713dde-b4e3-47d7-8be4-ad1f3f8c0cb2/examplediagram.credittingtingmutheuniversityofmanchester.png?10000
Scientists uncover magma heating effect that influences how volcanoes erupt /about/news/scientists-uncover-magma-heating-effect-that-influences-how-volcanoes-erupt/ /about/news/scientists-uncover-magma-heating-effect-that-influences-how-volcanoes-erupt/757221Journal: Nature Communications

Full title: Superheating in mafic magmas controls clinopyroxene nucleation delay and magma ascent dynamics

DOI: 10.1038/s41467-026-73352-1

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Scientists have shed light on a thermal process in magma that may help explain why similar volcanic systems can produce very different eruptive behaviours.

An international team, led by The University of Manchester, studied magma from the 2021 Tajogaite eruption on La Palma, Spain, and found that “superheating” — a state in which magma is heated above the temperature at which crystals are stable —  can strongly delay the formation of crystals as magma rises towards the Earth's surface.

Published in , the study shows that high temperatures can dissolve tiny pre-existing crystal "seeds" that normally help new crystals begin to form. Superheating also changes the internal structure of the magma, making it more uniform, and less able to support the formation of new crystals. This influences how quickly magma rises and how easily volcanic gases can escape, both of which play an important role in determining how explosive the eruption will be.

The findings help address a long-standing scientific debate about how a magma’s thermal history influences crystallisation processes before and during eruptions.

The researchers recreated volcanic conditions in the laboratory using magma from the Tajogaite eruption, which may have experienced some degree of superheating prior to eruption and during ascent.

Using synchrotron X-ray microtomography at Diamond Light Source, where crystallisation could be observed in real time, alongside complementary ex-situ experiments in Prague that allowed longer observation times, the team were able to track crystallisation processes under controlled conditions of high temperature and pressure.

They found that magma that had not been superheated began crystallising within around 20 minutes. In contrast, magma exposed to strong superheating, delayed crystal formation for more than eight hours.

The researchers then incorporated the experimentally measured nucleation delays into numerical models of magma ascent — simulations that predict how magma moves and evolves as it rises through the Earth’s crust.

The models showed that long crystallisation delays can allow magma to rise rapidly while remaining relatively fluid, potentially promoting dramatic lava fountaining behaviour. In contrast, magma that crystallises earlier becomes more viscous and ascends more slowly, allowing more time for gases to escape and favouring more gentle effusive behaviour.

The researchers say the findings could improve how scientists interpret volcanic monitoring signals and forecast eruption behaviour.

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Beyond Disclosure Day: The Real-World Protocols /about/news/beyond-disclosure-day-the-real-world-protocols/ /about/news/beyond-disclosure-day-the-real-world-protocols/757140Manchester astronomer leads global overhaul of rules for announcing the detection of extraterrestrial intelligenceA University of Manchester astronomer has led a major international overhaul of the rules that would govern how scientists announce evidence of extraterrestrial intelligence to the world.

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A University of Manchester astronomer has led a major international overhaul of the rules that would govern how scientists announce evidence of extraterrestrial intelligence to the world.

Professor Michael Garrett, the Sir Bernard Lovell Chair of Astrophysics, chaired a global effort to update the long-standing “post-detection protocols” used by researchers involved in the Search for Extraterrestrial Intelligence (SETI). The updated guidelines have now been formally ratified by the International Academy of Astronautics (IAA).

The revised Declaration of Principles marks the first major update to the protocols in more than 15 years and reflects a media landscape transformed by social media, artificial intelligence and the 24-hour news cycle.

Acknowledging that any credible detection of extraterrestrial technology would be a transformative event for humanity, the new Declaration establishes a rigorous framework for verification, transparency and global risk communication.

"The information environment we operate in today is vastly more complex than it was in 2010," said Professor Michael Garrett, Chair of the IAA SETI Committee. . "In an era of deepfakes, automated misinformation, and instant global connectivity, a single unverified claim could trigger confusion or panic. These new protocols ensure that scientists maintain the highest standards of evidence before making announcements to the world."

Adapting to a new era of SETI research

SETI and Technosignature research have expanded significantly since the previous protocols were adopted in 2010. Scientists now investigate the entire electromagnetic spectrum, including excess infrared heat signatures from megastructures, optical laser emission, and even multi-messenger signals. The updated Declaration explicitly recognises this broader approach.

It also addresses other modern challenges, including protections for researchers, acknowledging that scientists involved in potential detection could face harassment, doxxing, or intense media scrutiny.

It also acknowledges the risk of viral rumours, ensuring verified data is distinguished from hoaxes or terrestrial interference.

Verification before announcement

At the heart of the new rules is a reaffirmation of a core scientific principle: “extraordinary claims require extraordinary evidence”.

Under the revised protocols, no public announcement should be made until a signal or artifact has been rigorously authenticated by independent organisations using different instrumentation.

"We do not shout “alien” the moment we see a strange blip," Professor Garrett added. "The scientific method demands we check, check again, and then ask others to check. Only when we have reached a consensus that a signal is credible do we bring it to the world."

The 'No Reply' Consensus

While the protocols outline how to share news of a discovery, they remain firm on one critical restriction: No reply should be sent.

The Declaration reaffirms the enduring principle that transmitting a response to an extraterrestrial intelligence is a decision that belongs to all of humanity and should only take place following international consultations, specifically through the United Nations.

What happens next

With the updated Declaration ratified by the IAA Board, the aim is to see the document lodged with other stakeholders, including the United Nations. A formal technical presentation of the protocols to the wider community, including the scientific press, will take place at the International Astronautical Congress (IAC) later this year in Türkiye.

The IAA SETI Committee will also establish a permanent Post-Detection Sub-Committee, bringing together experts in social science, law, and ethics, to advise on the longer-term societal implications of a confirmed discovery.

The full document is available here: 

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Fri, 05 Jun 2026 16:08:41 +0100 https://content.presspage.com/uploads/1369/500_lovelltelescope-anthonyholloway-695535.jpg?10000 https://content.presspage.com/uploads/1369/lovelltelescope-anthonyholloway-695535.jpg?10000
World’s largest scorpion revealed from 415-million-year-old fossils /about/news/worlds-largest-scorpion-revealed-from-415-million-year-old-fossils/ /about/news/worlds-largest-scorpion-revealed-from-415-million-year-old-fossils/756842• Fossil fragments suggest Praearcturus gigas represents the largest scorpion ever discovered, perhaps one metre in length

• Specimens held in the Natural History Museum collection since the 1870s have been reinterpreted using modern techniques

• Giant scorpion lived tens of millions of years before other famous “giant” arthropods, reshaping ideas about how and why early arthropods grew so large

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Journal: Palaeontology

Full title: A revision of Praearcturus gigas: a giant scorpion from the Lower Devonian (Lochkovian) of Britain

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A giant scorpion that once roamed what is now England and Wales has been confirmed as the largest of its kind ever to exist, thanks to new research by scientists at The University of Manchester and the Natural History Museum.

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A giant scorpion that once roamed what is now England and Wales has been confirmed as the largest of its kind ever to exist, thanks to new research by scientists at The University of Manchester and the Natural History Museum.

Measuring around a metre in length and armed with pincers over 16 centimetres long, Praearcturus gigas would have been a formidable predator stalking floodplains around 415 million years ago. Remarkably, the fossils used to identify Praearcturus have been held in the Museum’s collection for more than 150 years.

The study, published in the journal, used modern analytical techniques and comparisons with newly described fossil species to suggest that Praearcturus is a scorpion, and a distinct species.

Dr Richard J. Howard, Curator of Fossil Arthropods at the Natural History Museum, London, and lead author of the study, said: “When we think of giant arthropods, people often picture Carboniferous rainforests with giant millipedes or dragonfly-like insects from later in Earth’s history. But Praearcturus lived at least 50 million years earlier, well before the evolution of trees, when life on land was only just getting started.

“Confirming that this animal is a scorpion fundamentally changes our understanding of how and when these creatures evolved to such extraordinary sizes.”

, Palaeontologist at The University of Manchester, added: “Praearcturus has puzzled us palaeontologists for more than a century. By bringing together material from several collections and using cutting edge imaging techniques , we've been able to build a clearer picture of the animal than was previously possible, which is really exciting.

“What makes Praearcturus so interesting is that it became enormous at a time when life on land was otherwise very small. But it was a world  that could somehow support a giant predator. To try and better understand this ancient world we compared the size of fossil scorpions with other animals alive at the time. To reach such extraordinary sizes, and conclude that perhaps it lived in water, where life was bigger.”

Praearcturus gigas lived during the Early Devonian. Small plants and fungi had only recently begun to spread across the landscape, and complex terrestrial ecosystems like forests had yet to evolve. This means that, unlike later giant arthropods, Praearcturus did not benefit from the high atmospheric oxygen levels associated with the rise of forests. Instead, its enormous size may reflect a world with relatively little competition from other large predators. This suggests that Praearcturus might have grown so big simply because there weren’t many other large animals around meaning it could dominate its environment in a way that wouldn’t be possible later on.

The fossils also hint that this giant scorpion may have led a partly aquatic lifestyle. Some specimens show flap-like structures on the abdomen similar to those found in modern crustaceans such as lobsters, suggesting it may have been capable of moving between water and land. Quantification of the wider arachnid fossil record, led by Dr Garwood and the team, shows that scorpions are unusually abundant in rocks of this age compared with other arachnids, supporting the idea that some early forms may have lived in freshwater environments where they are more likely to survive as fossils. This places Praearcturus at a pivotal moment in Earth’s history when animals were first experimenting with life outside the oceans.

 This places Praearcturus at a pivotal moment in Earth’s history when animals were first experimenting with life outside the oceans.

Dr Greg Edgecombe, Merit Researcher at the Natural History Musuem, London, and co-author of the study said: “The boundary between land and sea was much less defined at this time. Praearcturus gives us a fascinating glimpse into how early animals adapted to these changing environments.

“It may even represent a lineage that returned to the water after earlier ancestors had already begun living on land.”

First described in 1871, Praearcturus gigas was originally thought to be a giant crustacean, similar to a woodlouse. The known fossils fragmentary nature lacked key features such as a tail making it difficult to classify with confidence for more than a century.

The breakthrough came through comparison with better preserved fossils discovered in recent years, which revealed key anatomical features unique to scorpions. The discovery highlights the continuing scientific importance of museum collections.

Dr Howard added: “Specimens collected over a century ago can still hold entirely new insights. By revisiting them with modern techniques, we can uncover discoveries that reshape our understanding of life on Earth.”

The discovery of such a large scorpion so early in the history of life on land challenges assumptions about why prehistoric arthropods reached gigantic sizes. Rather than being driven solely by environmental factors such as oxygen levels, the findings suggest that ecological opportunity such as a lack of competition may have played a crucial role.

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Wed, 03 Jun 2026 14:40:12 +0100 https://content.presspage.com/uploads/1369/3def7881-2f6c-4916-b1cd-82c566f50a0d/500_lifereconstructionofpraearcturusgigascopyfranzanthonyhighres.png?10000 https://content.presspage.com/uploads/1369/3def7881-2f6c-4916-b1cd-82c566f50a0d/lifereconstructionofpraearcturusgigascopyfranzanthonyhighres.png?10000
Two Manchester Professors elected to prestigious Fellowship of the Royal Society /about/news/two-manchester-professors-elected-to-prestigious-fellowship-of-the-royal-society/ /about/news/two-manchester-professors-elected-to-prestigious-fellowship-of-the-royal-society/755650Two “outstanding researchers” from The University of Manchester have been elected to the Fellowship of the Royal Society, the UK’s national academy of sciences.

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Two “outstanding researchers” from The University of Manchester have been elected to the Fellowship of the Royal Society, the UK’s national academy of sciences.

Professor Chris Parkes, an experimental particle physicist at the University, and Professor Jeff Forshaw, a theoretical particle physicist, join over 90 other pioneers and leaders across a range of scientific fields, from astronomy and cancer research to mathematics and biotechnology.

In their election, they join the ranks of Stephen Hawking, Isaac Newton, Charles Darwin, Albert Einstein, Lise Meitner, Subrahmanyan Chandrasekhar and Dorothy Hodgkin.

Professor Parkes is Head of the Physics & Astronomy Department at The University of Manchester and is internationally recognised for his leadership in particle physics. He previously led the LHCb experiment at CERN - one of the world’s largest scientific collaborations. His research focuses on the search for new physics through studies of matter–antimatter asymmetries and the development of radiation-hard silicon detectors.

Professor Parkes has played a central role in the development of the next generation of LHCb experiments, serving as Principal Investigator and Project Manager for the UK’s contribution to the LHCb Upgrade, installed in 2023, and leading the design of the future LHCb Upgrade II programme. Last year, the LHCb collaboration was honoured by sharing the 2025 Breakthrough Prize in Fundamental Physics. Parkes was also awarded the Institute of Physics High Energy Physics Group Prize in 2010.

Professor Forshaw is a theoretical particle physicist best known for his work on quantum chromodynamics (QCD), the theory of the strong force. His work has uncovered unexpected features of perturbative QCD and has contributed to the theoretical frameworks used to interpret high-energy particle collisions, with important applications at the Large Hadron Collider (LHC) and other major international experiments. 

Jeff is also a prominent communicator of science. Together with Brian Cox he has written a series of bestselling popular science books that have introduced a wide readership to the mathematical ideas underpinning modern physics. Through his books, lectures and broader public engagement he has brought the substance, and the joy, of fundamental physics to a wide audience. 

Jeff's research has been recognised by the Maxwell Medal of the Institute of Physics for outstanding contributions to theoretical physics, and his public engagement work by the Institute's Kelvin Medal for outstanding and sustained contributions to the public understanding of physics. 

Sir Paul Nurse, President of the Royal Society, said: “I am delighted to welcome this newest group of exceptional scientists to the Fellowship of the Royal Society. 

“Their contributions reflect the highest standards of scientific endeavour. Whether advancing our understanding of vaccines or exploring the transformative potential of mathematics and computation, their work exemplifies the enduring value of curiosity, creativity and rigorous inquiry. 

“Our Fellowship is strengthened not only by individual distinction, but by the diversity of perspectives and experiences its members bring. This incoming cohort highlights the truly international character of contemporary science and underscores the vital role that plays in achieving breakthroughs that benefit us all.”

The full list of newly elected Fellows can be found on the

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Wed, 27 May 2026 11:11:14 +0100 https://content.presspage.com/uploads/1369/62cfc8ea-07bd-4e5f-b2e6-fb4dbc7dcc5f/500_untitleddesign4.png?10000 https://content.presspage.com/uploads/1369/62cfc8ea-07bd-4e5f-b2e6-fb4dbc7dcc5f/untitleddesign4.png?10000
Manchester researchers secure £1.3m to transform recycling of complex waste /about/news/manchester-researchers-secure-13m-to-transform-recycling-of-complex-waste/ /about/news/manchester-researchers-secure-13m-to-transform-recycling-of-complex-waste/753790The University of Manchester has been awarded over £1.3 million to develop technologies that could recover valuable materials from hard-to-recycle waste including disposable vapes and cars. 

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The University of Manchester has been awarded over £1.3 million to develop technologies that could recover valuable materials from hard-to-recycle waste including disposable vapes and cars. 

The three‑year project, REMOVE‑UM: REcovering MOlecular ValuE from Unrecycled Multi‑materials, funded by EPSRC and Defra will develop new technologies to tackle some of the most challenging waste products. 

Recycling has the potential to recover significant value from materials at the end of their life, playing a crucial role in building a more sustainable future. However, while current systems are effective for simple, single materials that can be easily sorted and cleaned, they struggle to deal with complex, multi-material products. 

Michael Shaver, Project Lead and Professor of Polymer Science at The University of Manchester, explains: “Recycling to recover value from materials at end-of-life is a tantalising component of a sustainable future. However, multi-material products – vapes, cars, batteries, furniture – comingle a host of plastics, metals, glass, ceramics and other materials designed to meet ever-increasing consumer demand for low-cost, high-performance, lightweight, aesthetically pleasing consumer goods. These staggeringly complex multi-materials are reaching their end-of-life with no strategy to facilitate the (re)integration of their components, materials or molecules into a circular economy.  

“Developing an economically viable and environmentally advantageous end of-life for multi-materials is vital. However, to achieve this in a just manner, it is essential we understand economic, societal, and environmental outcomes, coupling systemic approaches to ambitious fundamental research.” 

The REMOVE‑UM project will take a fundamentally new approach, developing methods to break down these materials at a molecular level and recover valuable components that can be reused. 

The work will combine expertise from across The University of Manchester, bringing together specialists in chemical recycling, catalysis, sustainability assessment and materials science.  

The project will focus on four key areas: 

  • Analysing waste streams to understand their composition and potential value 

  • Developing chemical processes to selectively break down complex materials into valuable products 

  • Separating recovered molecules efficiently while minimising environmental impact 

  • Working closely with industry partners to translate discoveries into real‑world applications and accelerate their commercial application. 

By targeting materials that current infrastructure cannot process, the team aims to complement existing recycling systems, rather than replace them.  

A core aim of the project is to ensure new recycling approaches are technically feasible, economically viable and environmentally sustainable. Life cycle assessment and economic analysis will be integrated throughout to guide decisions and deliver real benefits for society. The project also aims to cut reliance on fossil fuels by recovering reusable chemicals, while generating insights into how waste systems operate to reduce investment risk and support future recycling infrastructure. 

Dr Kedar Pandya, Executive Director for Strategy at EPSRC said: “This investment reflects our commitment to building a cleaner, more sustainable UK economy. By funding ambitious, collaborative and impactful research into recycling technologies, we are helping to tackle some of the most complex challenges in our waste system from collection through to currently hard-to-recycle material recovery. The research being undertaken, which is jointly funded by EPSRC and Defra, will support the long-term transition to a circular economy and creates the conditions for genuine economic and environmental benefit for the UK.” 

The project will be co-led by Dr Ciaran Lahive, Royal Academy of Engineering Research Fellow in the Department of Materials; Dr , Senior Lecturer in the Department of Chemical Engineering;  , Chair in Engineering Biology; , Professor of Chemical Engineering; and Dr , Dame Kathleen Ollerenshaw Fellow.  

It builds on sustained work in this area by these researchers, including:  

  • Chemical Recycling of Polycarbonate Acrylonitrile Butadiene Styrene Blends via Organocatalyzed Acetolysis, ChemSusChem, 
  • Recyclable Epoxy Composites Built with a Biobased Hardener, ACS Sustainable Chemistry & Engineering, 
  • Environmental Sustainability Assessment of Supercritical CO2 in Gel-spun UHMWPE Fibre Production, ACS Sustainable Chemistry & Engineering, 
  • Defining quality by quantifying degradation in the mechanical recycling of polyethylene, Nature Communications, 
  • Untangling the chemical complexity of plastics to improve life cycle outcomes, Nature Materials Reviews,   
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Tue, 26 May 2026 13:38:33 +0100 https://content.presspage.com/uploads/1369/a6f73a40-bb5a-4679-aaa9-c287222e09a1/500_reycling.jpg?10000 https://content.presspage.com/uploads/1369/a6f73a40-bb5a-4679-aaa9-c287222e09a1/reycling.jpg?10000
Scientists synthesise rare four‑nitrogen chain anions /about/news/scientists-synthesise-rare-fournitrogen-chain-anions/ /about/news/scientists-synthesise-rare-fournitrogen-chain-anions/748371Paper details:

Full title: Crystalline nitrogen chain radical anions 

Journal: Nature Chemistry 

DOI: 10.1038/s41557-025-02040-2

URL:  

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In findings, published in Nature Chemistry, researchers from the Universities of Manchester and Oxford have now demonstrated that a series of compounds containing {N₄}•– units can be reliably synthesised and characterised. The team prepared five distinct molecules, which showed surprising stability under ambient conditions, with one remaining intact in the solid state for several weeks.

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A team of scientists have synthesised a series of radical anions containing a rare four-atom nitrogen chain. 

Nitrogen is generally reluctant to form extended chains, largely because the N≡N triple bond is significantly stronger than N–N single or double bonds. As a result, radical anions based on four‑atom nitrogen chains have been especially difficult to isolate, typically requiring extreme environments such as those found high in the Earth’s atmosphere. 

In findings, published in , researchers from the Universities of Manchester and Oxford have now demonstrated that a series of compounds containing {N₄}•– units can be reliably synthesised and characterised. The team prepared five distinct molecules, which showed surprising stability under ambient conditions, with one remaining intact in the solid state for several weeks. 

Further reactivity studies revealed that these chains can fragment into N₁ and N₃ species, and can also serve as a source of nitrene radical anions. 

Detailed analysis showed how the nitrogen chain can break into smaller fragments, specifically single‑atom (N₁) and three‑atom (N₃) units. The researchers also found that these chains can act as a source of highly reactive nitrene radical anions. 

These findings provide new insight into the fundamental chemistry of nitrogen and demonstrate ways to control its reactivity under realistic conditions. 

Nitrogen chains are considered high‑energy‑density materials because they can release significant energy when they decompose into nitrogen gas. This property has long made them attractive for applications such as propellants, explosives, and gas‑generating systems. 

The ability to isolate and stabilise such molecules under ambient conditions could allow scientists to explore their use as “storable” reagents for transferring nitrogen groups in chemical reactions 

Beyond applications, the research offers a rare glimpse into a type of chemistry that plays a role in extreme environments, including the upper atmosphere where nitrogen chain ions have been detected. 

By recreating and stabilising these species in the laboratory, scientists can now investigate their properties in far greater detail, providing insights relevant to fields ranging from atmospheric chemistry to planetary science. 

This research was co-led by with Professor Meera Mehra, the University of Oxford, in collaboration with The University of Manchester’s , George F. S. Whitehead, , and, and Oxford’s Bono van IJzendoorn. First author was Oxford’s Reece Lister-Roberts. 
 

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Thu, 21 May 2026 17:14:34 +0100 https://content.presspage.com/uploads/1369/5019f30a-210f-4450-9ea0-d7b0a0ae67a0/500_scientistssynthesiserarefournitrogenchainanions.jpg?10000 https://content.presspage.com/uploads/1369/5019f30a-210f-4450-9ea0-d7b0a0ae67a0/scientistssynthesiserarefournitrogenchainanions.jpg?10000
Short exposures to common air pollutants shown to have distinct impacts on lung function and brain activity /about/news/short-exposures-to-common-air-pollutants-shown-to-have-distinct-impacts-on-lung-function-and-brain-activity/ /about/news/short-exposures-to-common-air-pollutants-shown-to-have-distinct-impacts-on-lung-function-and-brain-activity/744216Paper details:

Full title: Neurological and respiratory outcomes of the HIPTox controlled double-blind air pollution exposure trial

Journal: Nature Partner Journals Clean Air

DOI: 10.1038/s44407-026-00068-3

URL: 

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New research by a collaboration of UKbased scientists has revealed that common indoor and outdoor air pollutants can alter both brain and respiratory function within just four hours of exposure, offering key insights into how air pollution impacts brain health and may contribute to dementia risk.

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New research by a collaboration of UKbased scientists has revealed that common indoor and outdoor air pollutants can alter both brain and respiratory function within just four hours of exposure, offering key insights into how air pollution impacts brain health and may contribute to dementia risk.

Air pollution can influence the brain either directly, when harmful particles enter the brain, or indirectly, through inflammation in the lungs which then impacts the brain. Neurological diseases have been increasing for decades and there is now a greater appreciation that long term exposure to elevated levels of air pollution are associated in dementia risk. While we often categorise air quality by the total amount of particulate matter, this new study demonstrates that the source of the pollution matters as much as the quantity.

The findings in reveal that different pollutant sources produce varied health effects even at identical concentrations in the air. Recognising these differences is essential for shaping public policy, improving clinical diagnosis and developing protective strategies. With an ever‑growing ageing population and increasing urbanisation, the public‑health imperative to mitigate neurological disease becomes increasingly urgent.

Lead author Thomas Faherty of the University of Birmingham said: “This unique clinical study highlighted the importance of the lung–brain axis in brain responses to air pollution. Safely exposing the same individuals to multiple realworld pollution mixtures allowed us to detect differences between pollutants, demonstrating the value of this approach for further pollution-dementia research.”

In a doubleblind study involving 15 healthy volunteers, participants were exposed to clean air, limonene SOA (a citrus fragrance commonly used in cleaning products), diesel exhaust, woodsmoke and cooking emissions. After 60 minutes of exposure, and a four-hour break, researchers assessed respiratory function alongside working memory, selective attention, socioemotional processing, psychomotor speed and motor control.

Respiratory responses showed limonene had the greatest impact on lung function, followed by woodsmoke, diesel exhaust and finally cooking emissions.

Cognitive function was also found to be significantly influenced by pollutant source. Diesel exhaust and woodsmoke improved processing speed; limonenederived secondary organic aerosol enhanced working memory compared to cooking emissions; and diesel exhaust showed signs of impairing executive function. The team suggests that the presence of nitrogen oxides (NOX), known vasodilators, may alter blood flow to the brain and contribute to these mixed cognitive effects.

Given that measurable effects were detectable after a brief 60-minute exposure, the findings suggest that prolonged exposure could have significant longterm consequences for brain health. As rates of neurological disease increase, the study informs an immediate need for pollutant sourcespecific public health guidance, improved clinical awareness and more targeted strategies to protect vulnerable populations.

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Tue, 19 May 2026 10:49:15 +0100 https://content.presspage.com/uploads/1369/500_airpollution-2.jpg?10000 https://content.presspage.com/uploads/1369/airpollution-2.jpg?10000
Fault lines found to both drive and dampen volcanic activity /about/news/fault-lines-found-to-both-drive-and-dampen-volcanic-activity/ /about/news/fault-lines-found-to-both-drive-and-dampen-volcanic-activity/745147Paper details:

Full title: Fault-mediated magma propagation and triggered seismicity revealed by the 2022 São Jorge Azores unrest

Journal:

DOI: 10.1038/s41467-026-71668-6

URL: 

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Researchers have uncovered how major geological faults can simultaneously channel magma towards the surface and prevent volcanic eruptions, offering fresh insight into how eruptions begin, and why some never happen.

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Researchers have uncovered how major geological faults can simultaneously channel magma towards the surface and prevent volcanic eruptions, offering fresh insight into how eruptions begin, and why some never happen. 

The findings, published in , come from an international study examining a significant episode of volcanic unrest on São Jorge Island in the Azores in March 2022. 

By combining detailed earthquake records from land and seabed instruments with satellite-based measurements of ground movement, scientists were able to reconstruct how magma travelled deep beneath the island with unprecedented precision. 

The team discovered that a vertical sheet of magma, known as a dike, surged upwards from depths exceeding 20 kilometres before stalling just 1.6 kilometres below the surface. 

Surprisingly, much of this upward movement occurred with minimal seismic warning. Instead, earthquake activity intensified only after the magma’s ascent had slowed, presenting a challenge for eruption forecasting. 

Satellite data also showed that the island’s surface rose by around six centimetres during the event, confirming that magma had entered the upper crust. However, because the intrusion failed to reach the surface, no eruption occurred, a phenomenon scientists describe as a “failed eruption”. Such intrusions help to grow islands and this study’s unprecedented sharp earthquake maps show how this happens. 

The magma rose through one of the island’s main fault systems, the Pico do Carvão Fault Zone. By studying geological traces left by ancient earthquakes, scientists had previously found that this fault system has produced large earthquakes in the past. Rather than producing a single large earthquake, as seen in past seismic activity, the magma intrusion generated numerous small earthquakes distributed along the fault. 

The team, led by Dr Stephen Hicks, based at UCL Earth Sciences, conclude that the fault acted as both a conduit and a release mechanism. It provided a pathway for magma to rise, but also allowed gas and fluids to escape sideways, reducing pressure within the magma and ultimately halting its progress. 

Co-lead author Pablo J. González, of the Spanish National Research Council (IPNA-CSIC), explained: 
“The fault acted like both a highway and a leak. It helped magma rise, but may also have prevented an eruption.” 

, Reader in Marine Geophysics at The University of Manchester, supported the project as co-proponent and in discussing the results. 

The study demonstrates that significant magma movements can occur rapidly and with limited early warning signs, emphasising the importance of integrating multiple monitoring techniques to better assess volcanic risk. 

By combining onshore and offshore geophysical data, the researchers were able to achieve highly accurate detection and mapping of seismic activity and ground deformation, providing valuable information for local hazard assessments. 

The research reflects a large-scale collaborative effort, involving institutions across the UK, Portugal and Spain, supported by funding from organisations including the Natural Environment Research Council (NERC), the European Research Council, and Fundação para a Ciência e a Tecnologia. 
 
 

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Fri, 15 May 2026 17:13:28 +0100 https://content.presspage.com/uploads/1369/196e6f8a-a5e9-40d2-947f-ae24d6e36ea1/500_dji_0922.jpg?10000 https://content.presspage.com/uploads/1369/196e6f8a-a5e9-40d2-947f-ae24d6e36ea1/dji_0922.jpg?10000
New research reveals rapid methane release mechanism at the front of retreating ice sheets /about/news/new-research-reveals-rapid-methane-release-mechanism-at-the-front-of-retreating-ice-sheets/ /about/news/new-research-reveals-rapid-methane-release-mechanism-at-the-front-of-retreating-ice-sheets/744211Paper details:

Full title: Gas hydrate dissolution triggered by subglacial groundwater flushing during deglaciation

Journal: Nature Geoscience

DOI: 10.1038/s41561-026-01978-3

URL:

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An international team of scientists has discovered that methane hydrates beneath the northwest Greenland continental shelf became rapidly destabilised by meltwater, releasing large stores of methane during ice-sheet retreat across the continental shelf.

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An international team of scientists has discovered that methane hydrates beneath the northwest Greenland continental shelf became rapidly destabilised by meltwater, releasing large stores of methane during ice-sheet retreat across the continental shelf.

The findings, published in , suggest that this fastacting mechanism may have contributed to past climate events and could well contribute to future climate change as polar ice sheets continue to retreat.

The study draws on samples collected during the International Ocean Discovery Program (IODP) Expedition 400, one of the final missions of the decades longrunning global marine research programme. By analysing sediment cores drilled offshore in northwest Greenland, researchers found unexpectedly low methane concentrations in layers where methane hydrates would normally be abundant.

Highresolution 3D seismic imaging revealed widespread pockmarks and fluidescape structures on the seafloor, indicating that methanerich fluids had once migrated rapidly through the sediments. The evidence points to a striking conclusion, methane hydrates in this region were locally dissolved and flushed out by large volumes of meltwater during the last glacial cycle.

Scientists have long suspected that rapid methane release from destabilised hydrates may have played a role in major climate events in Earth’s history, including the Palaeocene–Eocene Thermal Maximum (PETM) around 56 million years ago. During this period, global temperatures rose by 5–8°C, triggering ocean acidification, species extinctions, and widespread environmental disruption. Although the Greenland findings relate to a much more recent period, they reveal a mechanism capable of producing similarly abrupt methane release under the right conditions.

Methane hydrates, icelike solids that trap methane within a crystalline structure, typically form under lowtemperature, highpressure conditions known as stability zones, typically found beneath permafrost or in deepsea sediments.

Approximately 1,800 Gigatons of methane is stored in gas hydrates beneath continental margins and permafrost, making them one of the largest methane reservoirs in the global carbon cycle and a massive potential greenhouse gas source.

Until now, destabilisation was thought to occur mainly through slow changes in temperature or pressure. The new findings reveal that meltwaterdriven dissolution can rapidly destabilise hydrates even within gas hydrate stability zones, previously thought of as safe stores of methane.

As ice sheets continue to thin and retreat, this newly identified process could influence the timing and magnitude of future methane emissions and shape the trajectory of climate change.

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Thu, 14 May 2026 10:00:00 +0100 https://content.presspage.com/uploads/1369/c4d34a57-80ad-4d12-ae1f-cd124e7bbe72/500_d93b67e7eb60f515b03f35482ca64edf.jpg?10000 https://content.presspage.com/uploads/1369/c4d34a57-80ad-4d12-ae1f-cd124e7bbe72/d93b67e7eb60f515b03f35482ca64edf.jpg?10000
University of Manchester Professor elected as Fellow of the Learned Society of Wales /about/news/university-of-manchester-professor-elected-as-fellow-of-the-learned-society-of-wales/ /about/news/university-of-manchester-professor-elected-as-fellow-of-the-learned-society-of-wales/743493Professor Apala Majumdar, Professor of Applied Mathematics at The University of Manchester, has been elected a Fellow of the Learned Society of Wales (LSW).

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Professor Apala Majumdar, Professor of Applied Mathematics at The University of Manchester, has been elected a .

She is one of 44 new Fellows announced this year, recognised for their outstanding contributions to research, innovation, leadership, and public life in Wales and beyond. Fellows of the LSW are part of distinguished body of interdisciplinary experts who promote, support, and advise on research and policy benefitting Wales by sharing their expertise, informing on policy, fostering collaboration, and providing mentorship.

Professor Hywel Thomas, President of the Learned Society of Wales, said: “Welcoming our new Fellows to the Society is always one of the highlights of the Society’s year. I congratulate them on this recognition of the excellence and importance of their work and contributions to life in Wales and beyond. We look forward to bringing their experience and knowledge to our work on policy and researcher development.”

Specialising in the mathematics of liquid crystals and partially ordered materials, Professor Majumdar’s research has been instrumental in advancing the field in an interdisciplinary context. Bridging mathematical modelling, applied analysis and theoretical physics, she has led international and interdisciplinary research networks, collaborating with partners across four continents.

Throughout her career, she has also been a committed advocate for Equality, Diversity and Inclusion (EDI), leading national and international initiatives to support underrepresented groups in mathematics. In 2015 she became the inaugural winner of the London Mathematical Society’s Anne Bennett Prize, awarded for contributions to mathematics and for inspiring women mathematicians. She also pioneered and co-led the hugely acclaimed “UK Retreats for Women in Applied Mathematics” from 2023-2026.

The 2026 cohort of LSW Fellows reflects the breadth of expertise across Welsh academia and civic society, spanning the arts, humanities, sciences, and engineering. This year marks a significant milestone for the Society, with 52% of new Fellows being women, the highest proportion in its history.

Professor Thomas added “I am also thrilled that our work on equity, diversity and inclusion is starting to see the Fellowship include increasing numbers of women. In three of the last five years, women have made almost or just over 50% of the new intake. This has been the result of concerted efforts to embed our EDI commitment at every turn, to make the nomination process more accessible, and to run a series of events that specifically target women academics and civic leaders who might be interested in joining the Fellowship.”

This year’s Fellows include leading figures in music, heritage, sculpture, climate science, coastal research, and ocean governance, highlighting Wales’s global contributions to cultural vitality and environmental stewardship. The Society also emphasised the growing importance of engineering and artificial intelligence, recognising researchers pioneering AI applications in manufacturing and innovators developing technologies to improve energy and carbon management in buildings.

Professor Majumdar’s election places her among a distinguished community of scholars whose achievements continue to shape Wales’s academic, cultural, and scientific landscape.

Professor Apala Majumdar said "I am delighted and honoured to be elected Fellow of the Learned Society of Wales. It is a fantastic opportunity to engage with the best minds in Wales, and to contribute to Welsh higher education and Welsh mathematics. Of course, none of this would have been possible without the support of my nominator, Professor Marco Marletta and my seconder, Professor Gennady Mishuris, and the generous and continuous encouragement of my parents and friends in Cardiff. I look forward to working closely with the Learned Society of Wales and bringing different communities together".

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Wed, 29 Apr 2026 11:03:44 +0100 https://content.presspage.com/uploads/1369/33aa3857-9f22-4f4e-b699-bc619fc376de/500_prof_apala_majumdar.jpg?10000 https://content.presspage.com/uploads/1369/33aa3857-9f22-4f4e-b699-bc619fc376de/prof_apala_majumdar.jpg?10000
New Self-Assembling Polymers Proven To Be Effective At Gene Delivery /about/news/new-self-assembling-polymers-proven-to-be-effective-at-gene-delivery/ /about/news/new-self-assembling-polymers-proven-to-be-effective-at-gene-delivery/743153Full title: Polymerization-Induced Electrostatic Self-Assembly Enables Noncytotoxic Polyplex Formation for Gene Delivery

Journal: ACS Materials Letters

DOI: 10.1021/acsmaterialslett.6c00077

URL:

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A collaboration of scientists at the University of Manchester and the University of Birmingham have explored a more effective and less toxic way of delivering genetic material into cells, a challenge central to areas such as gene therapy, biotechnology and genome editing.

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A collaboration of scientists at the University of Manchester and the University of Birmingham have explored a more effective and less toxic way of delivering genetic material into cells, a challenge central to areas such as gene therapy, biotechnology and genome editing.

This new technique utilises selfassembling polymer carriers for gene delivery, improving effectiveness and reducing the toxicity to cells over existing techniques in lab tests. These advances rely on safe and efficient methods for delivering gene‑editing tools into cells, which is a key bottleneck in enabling widespread application. Improving upon existing gene delivery methods has become essential to enable these developments and allow more effective transfection.

The process of introducing DNA or RNA into cells to change gene expression, can be achieved using viral or nonviral vectors. While viral vectors are powerful, they raise safety and manufacturing concerns, driving intense interest in the development of safer, nonviral alternatives. Transfection, using polymeric carriers or lipid nanoparticles to deliver genetic material, is a key nonviral strategy. However current systems often struggle to balance efficiency and toxicity. In order to develop polymer systems for molecular delivery applications, more advanced polymer systems need to be developed and screened.

In research published in ACS Materials Letters, the team demonstrates that polyplexes produced via PolymerizationInduced Electrostatic SelfAssembly (PIESA) offer a more effective and versatile route to gene delivery than conventional produced polymeric polyplexes. Polyplexes are formed when positively charged polymers bind to negatively charged DNA or RNA, creating nanoscale complexes that can enable genetic material to enter cells. Traditionally, polyplexes are prepared using pre-synthesised polymers which are then mixed with DNA or RNA. However, this postassembly step can lead to instability and increased cell toxicity, often limiting the size of genetic payloads that can be delivered effectively.

PIESA using PETRAFT (Photoinduced Electron/Energy Transfer Reversible Addition-Fragmentation Chain-Transfer) polymerisation overcomes these limitations by driving electrostatic selfassembly during polymer growth. As the polymer forms, it binds to the genetic material, producing polyplexes with controlled sizes, structures, and physicochemical properties. By using a “onepot approach to produce polyplexes, the need for complex postprocessing is avoided, resulting in improved consistency and facilitating highthroughput screening of formulations

The study shows that PIESAderived polyplexes are less toxic to cells than their conventionally assembled counterparts and act as more effective gene delivery vehicles in transfection trials, achieving higher gene expression while preserving cell viability.

Transitioning to advanced synthesis and assembly strategies such as PIESA could open the door to the nextgeneration of nonviral gene delivery systems, with improved transfection, broader formulation windows, and reduced cell toxicity.

Dr Lee Fielding added “This approach potentially opens up a more reliable and scalable route to non‑viral gene delivery. By innovating in how polyplexes can be prepared and screened for improved efficiency, while reducing toxicity, we hope it will help accelerate the development of gene delivery technologies and make them more accessible across biomedical research and clinical applications."

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What’s new in this work is that we combine controlled polymer synthesis and DNA assembly into a single, one‑pot process. By allowing the polyplexes to form as the polymer grows, we gain the ability to control their size and properties, whilst allowing for high-throughput screening of formulations in the future.”]]> Fri, 24 Apr 2026 13:55:52 +0100 https://content.presspage.com/uploads/1369/ce302eb8-856a-4c73-973b-e23549abe6d8/500_febstock-photo-dna-helix-gene-molecule-spiral-loop-d-genetic-chromosome-cell-dna-molecule-spiral-of-blue-light-1559659808.jpg?10000 https://content.presspage.com/uploads/1369/ce302eb8-856a-4c73-973b-e23549abe6d8/febstock-photo-dna-helix-gene-molecule-spiral-loop-d-genetic-chromosome-cell-dna-molecule-spiral-of-blue-light-1559659808.jpg?10000
Manchester Physicists Celebrate A Second Consecutive Year Of Success At The Breakthrough Prizes For Decades-Long Muon Experiment /about/news/manchester-physicists-celebrate-a-second-consecutive-year-of-success-at-the-breakthrough-prizes-for-decades-long-muon-experiment/ /about/news/manchester-physicists-celebrate-a-second-consecutive-year-of-success-at-the-breakthrough-prizes-for-decades-long-muon-experiment/743138The University of Manchester is celebrating a second consecutive year of success at the Breakthrough Prizes, with Manchester physicists again recognised for their leadership in one of the most ambitious and long‑running experiments in particle physics.

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The University of Manchester is celebrating a second consecutive year of success at the Breakthrough Prizes, with Manchester physicists again recognised for their leadership in one of the most ambitious and long‑running experiments in particle physics.

Researchers from Manchester are among the international team awarded the 2026 Breakthrough Prize in Fundamental Physics for their contributions to the Muon g‑2 experiment, a 60‑year scientific endeavour spanning CERN, Brookhaven National Laboratory and Fermilab. The prize follows Manchester’s prominent role in the 2025 Breakthrough Prize, awarded to the ATLAS and LHCb collaborations at CERN for precision tests of the Standard Model and discoveries including new particles and matter–antimatter asymmetries.

Valued at $3 million, the Breakthrough Prize is often dubbed the “Oscars of Science” and is considered the world’s premier science award. Unlike the Nobel Prize, which recognises up to three individuals or a single organisation, the Breakthrough Prize honours the approximately 350 collaborators across the world who produced the most precise measurement ever achieved at a particle accelerator: the anomalous magnetic moment of the muon.

Understanding the muon’s magnetic moment

Muons, one of the smallest known particles, interact with a sea of virtual particles that constantly flicker in and out of existence. Acting like tiny magnets, their magnetic moment shifts slightly due to these quantum effects. Comparing the measured value with theoretical predictions reveals the composition of this quantum “foam” and tests whether unknown particles or forces exist beyond the Standard Model.

Decades of increasingly precise measurements now indicate that the Standard Model remains our best description of fundamental physics.

Manchester leadership across UK institutions

The UK played a central role in the collaboration, providing one of the experiment’s two major detector systems and in developing simulations and software to analyse the data alongside contributions to the theoretical calculations.

Professor Mark Lancaster, from The University of Manchester, led the UK involvement across Manchester, Lancaster, Liverpool and UCL, and served as co‑spokesperson of the global Fermilab Muon g-2 collaboration between 2018 and 2020.

A global scientific milestone

The Muon g‑2 experiments began at CERN in the 1970s, moved to Brookhaven in the 1990s and concluded at Fermilab with the final publication in 2025. The goal was to measure the muon’s magnetic moment with ever‑increasing precision, probing the quantum vacuum where virtual particles appear and vanish. Even the smallest deviation from theoretical predictions could point to new physics beyond the Standard Model.

The achievement represents the combined effort of scientists and engineers across multiple disciplines, reflecting the scale and diversity of expertise required to reach record‑breaking precision.

With Manchester researchers again at the forefront of a globally celebrated breakthrough, the University continues to demonstrate its leadership in shaping the future of particle physics and advancing our understanding of the fundamental laws of nature.

Professor Mark Lancaster FRS said “Our attention at Manchester now turns to a next generation of experiments that are striving to find evidence of new particles and interactions using novel quantum technologies” 

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Fri, 24 Apr 2026 11:39:54 +0100 https://content.presspage.com/uploads/1369/2c784161-669a-4cc8-9102-208f3299c755/500_g-2-ring.jpg?10000 https://content.presspage.com/uploads/1369/2c784161-669a-4cc8-9102-208f3299c755/g-2-ring.jpg?10000
The ICAM Renews Collaboration Framework Agreement with Expanded Scope /about/news/the-icam-renews-collaboration-framework-agreement-with-expanded-scope/ /about/news/the-icam-renews-collaboration-framework-agreement-with-expanded-scope/742004The International Centre for Advanced Materials (ICAM) is pleased to announce the extension of its well-established academic–industry collaboration framework agreement broadening its scope to include a wider range of topics including materials, chemistry, catalysis, biosciences, and subsurface, with a focus on enabling technologies that support bp’s ambition to deliver energy to the world, today and tomorrow.

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The International Centre for Advanced Materials (ICAM) is pleased to announce the extension of its well-established academic–industry collaboration framework agreement broadening its scope to include a wider range of topics including materials, chemistry, catalysis, biosciences, and subsurface, with a focus on enabling technologies that support bp’s ambition to deliver energy to the world, today and tomorrow.

The ICAM is a successful partnership between bp, The University of Manchester, University of Cambridge, Imperial College London and the University of Illinois Urbana-Champaign. Since its launch in 2012, the ICAM has supported research ranging from PhD-led exploratory projects to large-scale strategic initiatives involving multiple teams. The Centre has strengthened research capabilities, fostered interdisciplinary collaboration and provided students and early career researchers with valuable experience working alongside bp experts. Its model embeds bp Mentors within project teams, ensuring research remains industrially relevant and accelerates translation from laboratory to application.

The ICAM’s Next Chapter

Building on more than a decade of interdisciplinary research in materials science, the ICAM will continue to make a difference in today’s energy systems and help build tomorrow’s, while aligning with bp’s strategic interests and technology roadmaps.

The ICAM’s research supports bp’s ambition to be a net zero company and to help get the world to net zero by 2050 or sooner by improving understanding of materials, processes and energy systems that can lower emissions and enhance performance. Recent examples include research on sustainable catalysts for CO₂ conversion through the ICAM's EPSRC Prosperity Partnership on Sustainable Catalysis for Clean Growth, and work to develop better modelling tools for sustainable aviation fuel.

In recent years, the ICAM has welcomed additional expertise from associate members including Cardiff University and Johnson Matthey, both central to its previously mentioned Prosperity Partnership as well as University College London, University of Edinburgh, University of Leeds, University of Sheffield and University of Texas at Austin.

In its next chapter, the ICAM will continue to exemplify what can be achieved when industry and academia work together to address energy challenges.

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Wed, 15 Apr 2026 10:00:00 +0100 https://content.presspage.com/uploads/1369/e27ef410-4e7f-42ac-8022-45b9306ccdfb/500_20251015-2025icamconference-70a2744.jpg?10000 https://content.presspage.com/uploads/1369/e27ef410-4e7f-42ac-8022-45b9306ccdfb/20251015-2025icamconference-70a2744.jpg?10000
New research brings machine‑learning‑based physics a step closer to solving real engineering challenges. /about/news/new-research-brings-machinelearningbased-physics-a-step-closer-to-solving-real-engineering-challenges/ /about/news/new-research-brings-machinelearningbased-physics-a-step-closer-to-solving-real-engineering-challenges/741503Full title: Machine learning for hydrodynamic stability

Journal: Journal of Computational Physics

DOI: 10.1016/j.jcp.2026.114743

URL:

Contact:

James Schofield, News and Media Relations Officer: james.schofield-3@manchester.ac.uk

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A mathematics professor at The University of Manchester has developed a novel machine-learning method to detect sudden changes in fluid behaviour, improving speed and cost of identifying these instabilities and overcoming one of the major obstacles faced when using machine learning to simulate physical systems.

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A mathematics professor at The University of Manchester has developed a novel machine-learning method to detect sudden changes in fluid behaviour, improving speed and cost of identifying these instabilities and overcoming one of the major obstacles faced when using machine learning to simulate physical systems.

Computational simulations of mathematical models of fluid flow are essential for everyday applications ranging from predicting the weather to the assessment of nuclear reactor safety. The advent of this simulation capability over the past 50 year has revolutionised the development of fuel-efficient aeroplanes and sail configurations on racing yachts can now be optimised in real time, providing the marginal gains needed to win races in the Americas Cup.

Optimised aerodynamics means that modern day cyclists can ride faster, golf balls fly further and Olympic swimmers consistently set world records. Computational fluid dynamics also enables the modelling of the flow of blood in the human heart, making the provision of patient-specific surgery possible.

Scientists and engineers rely on computer-based simulations to understand, predict, and design these systems that they can’t easily test in real life. But traditional fluid‑simulation methods often require hours or even days of computation, and struggle when the flow becomes fast or highly complex. 

Machine‑learning‑based simulations, once trained, can make these assessments almost instantly. Instant feedback would allow rapid design testing, real‑time adjustments, and rapid testing variation without the usual computational burden.

The findings were published in the

The study uses the stability of fluid motion as the foundation for a new method that predicts how complex systems behave. Instead of relying on costly laboratory experiments, solutions to the fundamental equations of fluid motion are generated numerically. This allows the machine-learning model to be trained on accurate, high-quality data drawn directly from physics, demonstrating that the model can accurately handle challenging simulations.

A key focus of the work is identifying bifurcation points –the moments when a smooth, steady flow (laminar flow) suddenly begins to change – similar to calm, evenly flowing river as it hits an obstruction, or splits and fluids start to mix and form eddies. Laminar flow is when a liquid behaves in a smooth and orderly way, like pouring honey, the flow is consistent and steady.

By successfully using a machine‑learning model to identify the points at which a system changes behaviour or in this case bifurcates, the study suggests that, with further refinement, machine‑learning‑based models could become a practical alternative to traditional fluid‑modelling techniques in the future.

Professor Silvester added: "This marriage of old and new approaches holds the promise of efficient computation of physically realistic fluid flows in a myriad of practical situations. The development of refined mathematical models of complex fluids is likely to be critically important if the promise of AI is to be effectively realised in the future.”

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Thu, 09 Apr 2026 10:58:45 +0100 https://content.presspage.com/uploads/1369/a57da138-5502-4735-ad2f-6966c2135b00/500_computer-hands-close-up-concept-450w-2275082489.jpg?10000 https://content.presspage.com/uploads/1369/a57da138-5502-4735-ad2f-6966c2135b00/computer-hands-close-up-concept-450w-2275082489.jpg?10000
Manchester Professor appointed expert reviewer for Government nuclear decommissioning review /about/news/manchester-professor-appointed-expert-reviewer-for-government-nuclear-decommissioning-review/ /about/news/manchester-professor-appointed-expert-reviewer-for-government-nuclear-decommissioning-review/740979A University of Manchester Professor has been appointed by  Lord Vallance, Minister of State for Science, Innovation, Research and Nuclear, as an Expert Reviewer for an independent assessment of the Nuclear Decommissioning Authority (NDA);  an executive non-departmental public body that is charged with, on behalf of government, the mission to clean-up the UK’s earliest nuclear sites safely, securely and cost effectively.

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A University of Manchester Professor has been appointed by  Lord Vallance, Minister of State for Science, Innovation, Research and Nuclear, as an Expert Reviewer for an independent assessment of the Nuclear Decommissioning Authority (NDA);  an executive non-departmental public body that is charged with, on behalf of government, the mission to clean-up the UK’s earliest nuclear sites safely, securely and cost effectively.

Professor Zara Hodgson FREng is an internationally recognised expert in nuclear energy policy and research, and Director of the University’s Dalton Nuclear Institute. She has been appointed to support the NDA 2026 Review, which has been commissioned by the Government to provide assurance on the NDA’s performance and governance, and to make recommendations on improvements.

The Review is led by Dr Tim Stone CBE, a senior expert adviser to five previous Secretaries of State in two successive UK governments and the Chair of Nuclear Risk Insurers. Professor Hodgson will join a team of three other independent experts to support Dr Stone.

The review will focus on the NDA’s strategic planning and management, project and programme delivery, and financial management. It will assess how effectively the NDA delivers value for money for the taxpayer while maintaining the highest standards of safety, transparency and governance across the UK’s civil nuclear legacy. Reviewers will challenge current practices, propose bold value-for-money recommendations, and highlight good practice while identifying areas for improvement.

Professor Hodgson is a Professor of Nuclear Engineering at The University of Manchester and has played a pivotal role in recent UK Government interventions to grow the UK’s nuclear fuel production capability. Her work has supported the UK’s Net Zero ambitions, strengthened energy security and helped build more resilient nuclear supply chains. At Manchester, she leads contributions to national nuclear programmes through high impact research, education and training, and independent advice.

Professor Hodgson’s appointment reflects The University of Manchester’s leadership in nuclear research and policy, and its long-standing role in providing independent expertise to inform national decision-making.

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Wed, 01 Apr 2026 12:28:18 +0100 https://content.presspage.com/uploads/1369/86bb9568-cbf8-45d7-95ec-17527863a37d/500_dsc09907headneat.jpg?10000 https://content.presspage.com/uploads/1369/86bb9568-cbf8-45d7-95ec-17527863a37d/dsc09907headneat.jpg?10000
Crushing soda cans and the mathematics of corrugation formation /about/news/crushing-soda-cans-and-the-mathematics-of-corrugation-formation/ /about/news/crushing-soda-cans-and-the-mathematics-of-corrugation-formation/740817Journal: Communications Physics 

Full title: Soda-forming: Sequential buckling in fluid-filled cylindrical shells

DOI: 10.1038/s42005-026-02589-5 

URL: 

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Many people have likely found themselves watching oddly satisfying videos of random objects being squashed by a powerful hydraulic press, but rarely people consider why things squash the way they do.

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Many people have likely found themselves watching oddly satisfying videos of random objects being squashed by a powerful hydraulic press, but rarely people consider why things squash the way they do.

One object that caught the eye of researchers at The University of Manchester was a simple drinks can. When crushed while filled with liquid, it behaves completely differently from an empty one. Instead of collapsing suddenly, it produces an ordered sequence of circular rings that appear one by one.

But it turns out there’s more going on than just a satisfying visual. Published in the journal , the Manchester team has discovered that the formation of corrugations follows a rare mathematical process - and the discovery could have implications for safety across multiple industries.

Lead researcher, , PhD researcher at The University of Manchester, said: “Most of us have stamped on an empty can and watched it collapse instantly. But a full can behaves completely differently. It forms one buckle after another in an orderly fashion, until the whole can is wrapped in evenly spaced corrugations. We were fascinated and wanted to understand what was driving that behaviour – particularly as liquid-filled containers are found everywhere in our day-to-day lives.”

To find out, the researchers combined laboratory experiments with a type of mathematical modelling typically used to study natural pattern formation, such as water ripples or wave formations.

They discovered that the sequence of buckles is anything but random. Because the liquid inside the can is almost incompressible, it changes the way the aluminium can carries force.

“A standard can usually starts to buckle near the middle,” explained , Reader in Nonlinear Dynamics at The University of Manchester. “But tiny variations in shape or size of the can, can shift where the first ring appears. After that, however, the physics takes over, and the sequence becomes extremely predictable. As the can compresses, the metal softens and then stiffens again – this cycle naturally forms the rings. Even changes in the can’s internal pressure don’t alter the overall pattern much. That tells us that the buckling sequence is a fundamental property of any liquid-filled cylinder made from metal, not just a quirky effect of a drinks can.”

The team discovered that this step-by-step pattern matches a mathematical process known as homoclinic snaking - a phenomenon where bumps or ripples appear one by one in a precise, controlled order. Although mathematicians have suggested that this ‘snaking’ could underpin the buckling of cylinders, uncovering its trace in a real physical system is exceptionally rare.

The findings could also have far broader implications. Liquid-filled metal cylindrical shells are used throughout modern engineering — in industrial storage, transportation, construction, energy systems, and even in parts of rockets.

Yet, despite their ubiquity, engineers have lacked a clear understanding of how these structures might buckle when compressed.

, Royal Society University Research Fellow at The University of Manchester. said: “Understanding the exact sequence of buckles could help engineers spot the early warning signs of failure long before a system collapses. That could lead to safer designs, better monitoring techniques, and more reliable structures in a whole range of industries. It might even open up possibilities for manufacturing. For example, it could be possible to create corrugated cans after filling without needing a mould.”

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Tue, 31 Mar 2026 15:51:00 +0100 https://content.presspage.com/uploads/1369/7b2bd32b-3084-4b3f-838e-5c76ca49ef89/500_screenshot2026-03-31152352.png?42294 https://content.presspage.com/uploads/1369/7b2bd32b-3084-4b3f-838e-5c76ca49ef89/screenshot2026-03-31152352.png?42294
The University of Manchester signs Memorandum of Understanding with United Utilities /about/news/the-university-of-manchester-signs-memorandum-of-understanding-with-united-utilities/ /about/news/the-university-of-manchester-signs-memorandum-of-understanding-with-united-utilities/740539The University of Manchester and United Utilities have signed a Memorandum of Understanding (MoU) to advance research and innovation in the water sector.

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The University of Manchester and United Utilities have signed a Memorandum of Understanding (MoU) to advance research and innovation in the water sector.

Building on existing collaboration, the partnership aims to address both immediate and longer-term challenges across the water industry, including climate resilience, water quality, wastewater management and resource optimisation.  

The partnership comes at an important time for the sector, as it undergoes rapid transformation in response to climate change, population growth, and an evolving policy and regulatory environment. The University will support this challenge by providing research-driven solutions that support water quantity and quality for communities and the environment.

Under the MoU, the University and United Utilities will expand engagement across strategic innovation priorities, aligning academic expertise with company needs and opportunities, to deliver tangible, real-world impact.

On a visit to the University, the group toured the robotics lab based in the University’s flagship engineering building, observing some of the cutting-edge robotics equipment that is being developed for real-world applications.

Recent collaborative projects between the two organisations include the use of robotics for water network inspection, and a digital twin for the GMCA Integrated Water Management Plan.

Sarah Sharples, Vice President and Dean of the Faculty of Science and Engineering, said: "This partnership marks an important step in uniting academic excellence with industry expertise to address the evolving challenges of the water sector. Together, we aim to drive innovation opportunities that benefit students, research, and society."

Dr Louise Bates, Director of Business Engagement and Knowledge Exchange at The University of Manchester, said: “Collaboration between The University of Manchester and United Utilities dates back to 2006, and in recent years it has really grown through joint research and student-focused activities. This has created a strong foundation for us to build on through this new Memorandum of Understanding.” 

Jo Harrison, Director of Asset Management at United Utilities, said: “We are passionate about securing resilient services for the North West, both now and for the future.

"This partnership builds on a strong foundation of collaboration and gives us an exciting opportunity to bring together world-class academic insight with practical, real-world experience. By combining our strengths, we can make a meaningful and lasting difference on the ground, helping to deliver a stronger, greener and healthier North West for generations to come.”

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Fri, 27 Mar 2026 13:34:20 +0000 https://content.presspage.com/uploads/1369/d257b40b-96d6-4973-a3b0-6a176b866fa1/500_uomxunitedutilities.jpeg?10000 https://content.presspage.com/uploads/1369/d257b40b-96d6-4973-a3b0-6a176b866fa1/uomxunitedutilities.jpeg?10000
University of Manchester supports landmark Russell Group commitment to build healthier communities /about/news/university-of-manchester-supports-landmark-russell-group-commitment-to-build-healthier-communities/ /about/news/university-of-manchester-supports-landmark-russell-group-commitment-to-build-healthier-communities/740266The University of Manchester is backing a major new commitment alongside Russell Group universities to build a healthier future for the UK, working in partnership with the NHS, national and local government, industry and the local community.

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The University of Manchester is backing a major new commitment alongside Russell Group universities to build a healthier future for the UK, working in partnership with the NHS, national and local government, industry and the local community.

Announced on Tuesday (24 March), the Russell Group’s 24 leading universities, including The University of Manchester, set out plans to train more than 181,000 students in subjects critical to health and care by 2030 – an increase of more than 15%. This includes doctors, dentists, nurses and midwives delivering frontline care, alongside engineers, social scientists and technology specialists whose expertise is increasingly essential to improving today’s healthcare services.

The University of Manchester already educates around 3,000 medical and dentistry students, and Russell Group universities in the North West collectively train over 17,000 people in the skills we need for a healthier future.  

The commitment will also support the growth of life sciences companies, helping to bring new treatments, technologies and high-skilled jobs to communities across the country.

While expanding training, universities will also work to remove barriers so that more students from disadvantaged backgrounds can access medical and health careers. This includes expanding initiatives, such as targeted gateway courses, summer schools and mentoring that make health and care careers more open to students from all backgrounds.

At The University of Manchester, the commitment builds on a long-standing focus on widening participation and supporting regional skills needs, particularly across Greater Manchester and the North West.

Professor Duncan Ivison, President and Vice-Chancellor of The University of Manchester, who is chairing the Russell Group working group behind the commitment, said: “One thing that distinguishes Russell Group universities – like The University of Manchester – is our unique combination of groundbreaking discovery research and our role in training the health workforce of the future.

“Our commitment is to training 181,000 graduates in health and care-related subjects by 2030, a 15% increase; increasing access for students from all backgrounds to join these vital professions; and supporting the growth of life sciences and innovation to help create high-skilled jobs and attract investment into communities.

“And we’re going to do it in partnership with the NHS and the patients, families, workers, industries and communities we serve. It’s about ensuring that the work of our universities translates into meaningful, real-world impact.

“There is more to do, but this represents an important step forward.”

The University of Manchester recently formed a new partnership with Wigan & Leigh College and the Greater Manchester Colleges network to place PhD researchers into Further Education classrooms, helping to strengthen teaching in priority subjects such as engineering, digital skills and STEM. The programme helps colleges with specialist expertise, while giving postgraduate researchers valuable teaching experience and building stronger links between further and higher education.

Other recent initiatives include hands-on pharmacy workshops and Healthcare Careers Pathway Days, offering students opportunities to meet professionals, visit campus and gain practical advice on applications.

The University also runs , such as Lancashire Access Medics and the , designed to support students from disadvantaged backgrounds into medicine.

While delivering on these commitments, Russell Group universities will for the first time convene a nationwide series of community engagement events.

The University of Manchester will host an in-person roundtable event bringing together partners from across the region to explore the future of the healthcare workforce. It will focus on how The University of Manchester can work with the health ecosystem in Greater Manchester to expand inclusive pathways into health careers and secure a strong and sustainable pipeline of talent for the NHS.

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Wed, 25 Mar 2026 11:35:10 +0000 https://content.presspage.com/uploads/1369/628d7011-ae34-4ced-b04f-59688aa4379c/500_gc_uom_mhs_dentistry-418.jpg?10000 https://content.presspage.com/uploads/1369/628d7011-ae34-4ced-b04f-59688aa4379c/gc_uom_mhs_dentistry-418.jpg?10000
Inspiring the next generation: Great Science Share for Schools continues to make a difference /about/news/inspiring-the-next-generation-great-science-share-for-schools-continues-to-make-a-difference/ /about/news/inspiring-the-next-generation-great-science-share-for-schools-continues-to-make-a-difference/739866The University of Manchester’s Great Science Share for Schools (GSSfS) is continuing to inspire young people around the world to become curious, confident scientists.

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The University of Manchester’s Great Science Share for Schools (GSSfS) is continuing to inspire young people around the world to become curious, confident scientists.

Led by the University’s Science & Engineering Education Research and Innovation Hub (SEERIH), the Great Science Share for Schools encourages pupils aged 5–14 to ask, investigate and share scientific questions that matter to them. By placing curiosity at the centre of learning, it supports the development of scientific literacy, creativity and confidence from an early age empowering children to see themselves as active participants in science.

Its reach and inclusivity are among its greatest strengths and Great Science Share for Schools continues to build global momentum. In 2025 alone, more than 845,000 young people from over 4300 schools in 52 countries took part, with around 50% of participants located in areas of high socio-economic deprivation. This reflects the initiative’s position as a worldwide leader in child-centred science engagement and its strong commitment to widening access and ensuring science is accessible to all, regardless of background.

The University continues to play a central role in this growth. In 2025, during the programme’s 10thanniversary year, we welcomed over 35 schools from across Greater Manchester onto campus for hands‑on science activities that connected children directly with our colleagues, facilities and scientific community.

With the campaign having received patronage of the UK National Commission for UNESCO in 2024, 2025 and 2026, focus is now on the global growth of GSSfS. With its inclusive, non-competitive and collaborative approach, the format is easily translatable to 5–14-year-olds across the globe to ask a scientific question, investigating it and sharing it in various means of communication.

Great Science Share for Schools provides opportunities for university academics and research to feature in the campaign through the resources produced each year. The campaign has also worked closely with Manchester Museum staff and the University’s Creative Manchester.

The impact of Great Science Share for Schools over the past decade was recently recognised in a feature in the , which highlighted the programme’s Manchester roots, its global influence and its success in empowering hundreds of thousands of children to explore the world around them. By nurturing curiosity, confidence and a lifelong love of science, the initiative continues to demonstrate the power of meaningful engagement with young learners.

  • Further information can be found here on the .
  • Please contact us if you are interested in collaborating on the campaign.
  • See the full article in the 
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Light-activated material offers new approach to carbon dioxide conversion /about/news/light-activated-material-offers-new-approach-to-carbon-dioxide-conversion/ /about/news/light-activated-material-offers-new-approach-to-carbon-dioxide-conversion/739178Scientists have developed a new material that can use sunlight and water to convert carbon dioxide (CO₂) into carbon monoxide (CO) – a key building block for making fuels, plastics, pharmaceuticals and other everyday chemicals.

The finding, led by The University of Manchester, could support the development of future technologies that recycle greenhouse gases to make fuels and useful chemicals, more sustainably, using nothing more than light and water.

CO2 is the main driver of human-caused climate change, but it is also an abundant carbon resource. Finding efficient ways to convert CO₂ already in the atmosphere into useful products is a major scientific challenge.

The team’s new catalyst, published today in the Society, combines ideas from biology and materials science to address the problem.

, Professor of Chemistry at The University of Manchester, said: “In nature, specialised enzymes can bind and release small molecules like CO₂ with remarkable control. We have been able to design a solid material that behaves in a similar way. It is activated by visible light to react and convert CO2 and the original material is then regenerated to react with more CO2”.

The work revolves around metal-organic frameworks (MOFs) - materials made from metal atoms or clusters  connected by organic linkers to form porous networks of tiny cavities in which molecules can be adsorbed and activated for conversion to new products, in this case CO2 .

The researchers used a cerium-based MOF, built using organic linkers that contain amino groups to improve how it absorbs light. When illuminated, the material briefly undergoes an electronic change, creating temporary “open” sites in its pores that can grab hold of CO₂ molecules. They then react and convert into CO before being released again.

This reversible binding behaviour is similar to how enzymes in living systems handle small molecules such as CO₂.

In laboratory experiments, the new catalyst produces CO extremely efficiently, with no detectable by-products, outperforming many existing benchmark materials.

Unlike other existing systems, the process does not require precious metals or added chemicals that are consumed during the reaction. It also avoids producing large amounts of hydrogen instead of useful carbon-based products.

The new system uses only light, water and CO₂, and produces one single valuable product.

Prof Sihai Yang, said: “Our research is still at a fundamental stage, but the findings provide a clear blueprint for designing next-generation catalysts that turn waste CO₂ into useful chemicals.

 “By learning from how nature controls chemical reactions, we can begin to design materials that open up exciting possibilities for clean and efficient energy technologies.”

The researchers believe the principles demonstrated here could be applied to a wide range of reactions, helping to accelerate the development of sustainable solar-to-fuel technologies.

This research was publihsed in the Journal of the American Chemical Society

Full title: Light-induced Binding and Reduction of CO2 over Transient Open Ce(III) Sites in a Metal-Organic Framework

DOI:

URL: 

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Tue, 17 Mar 2026 09:42:14 +0000 https://content.presspage.com/uploads/1369/5b132475-2654-48ee-890c-6f2b807f6f9d/500_chemistrylabs20.jpg?10000 https://content.presspage.com/uploads/1369/5b132475-2654-48ee-890c-6f2b807f6f9d/chemistrylabs20.jpg?10000
University of Manchester scientists play key role in discovery of new heavy-proton particle at CERN /about/news/university-of-manchester-scientists-play-key-role-in-discovery-of-new-heavy-proton-particle-at-cern/ /about/news/university-of-manchester-scientists-play-key-role-in-discovery-of-new-heavy-proton-particle-at-cern/739172Scientists from the University of Manchester have played a leading role in the discovery of a new subatomic particle at CERN’s Large Hadron Collider (LHC). The particle, known as the Ξcc⁺ (Xi‑cc‑plus), is a new type of heavy proton-like particle containing two charm quarks and one down quark.

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Scientists from the University of Manchester have played a leading role in the discovery of a new subatomic particle at CERN’s Large Hadron Collider (LHC). The particle, known as the Ξcc⁺ (Xi‑cc‑plus), is a new type of heavy proton-like particle containing two charm quarks and one down quark.

The result is the first particle discovery made using the upgraded LHCb detector, a major international project involving more than 1,000 scientists across 20 countries. The UK made the largest national contribution to the upgrade, with significant leadership from Manchester.

The newly observed Ξcc⁺ is a heavier relative of the proton, which was famously discovered in Manchester by Ernest Rutherford and colleagues in 1917-1919. The proton contains two up quarks and a down quark. The new discovery replaces the up quarks with their heavier relatives the charm quarks. It also extends a legacy begun in the 1950s, when Manchester physicists were the first to identify a member of the Ξ (Xi) particle family.

Professor Chris Parkes, head of the University’s Department of Physics and Astronomy, led the international collaboration during the installation and first operation of the LHCb Upgrade detector. He also led the UK contribution to the project for over a decade, from approval through to delivery.

The Manchester LHCb group designed and built key components of the upgraded tracking system, the silicon pixel detector modules assembled in the University’s Schuster Building. These detectors are central to precisely reconstructing the particle decays in which the Ξcc⁺ signal was observed.

said: “Rutherford’s gold‑foil experiment in a Manchester basement transformed our understanding of matter, and today’s discovery builds on that legacy using state‑of‑the‑art technology at CERN. Both milestones demonstrate just how far curiosity driven research can take us. This discovery showcases the extraordinary capability of the upgraded LHCb detector and the strength of UK and Manchester contributions to the experiment.”

, from The University of Manchester, who led the silicon detector module production, added: “The detector is a form of ‘camera’ that images the particles produced at the LHC and takes photographs 40 million times per second. It utilises a custom designed silicon chip that also has a variant for use in medical imaging applications.”

The Ξcc⁺ particle was identified through its decay into three lighter particles (Λc⁺ K⁻ π⁺), recorded in proton‑proton collisions at the LHC in 2024, the first year of full operation of the LHCb Upgrade experiment. A clear peak of around 915 events was observed at a mass of 3619.97 MeV/c², consistent with expectations based on a previously discovered partner particle, the Ξcc⁺⁺.

This observation resolves a question that had remained open for more than two decades since an unconfirmed claim of the observation of this particle was made. The particle has now been discovered by LHCb at a mass incompatible with this earlier claim and a mass that is compatible with the theoretical expectations based on the partner particle.

In the next phase of the LHC programme, The University of Manchester is playing a leading role in LHCb Upgrade 2, which is planned to take advantage of the High-Luminosity LHC accelerator. 

Professor Parkes added: "This discovery highlights the exciting scientific opportunities ahead as we prepare for the next generation of upgrades. Continued UK involvement in LHCb Upgrade 2 will be key to ensuring the UK remains at the forefront of particle physics."

Details of the Ξcc⁺ discovery are presented at the Rencontres de Moriond Electroweak conference.

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Tue, 17 Mar 2026 08:06:49 +0000 https://content.presspage.com/uploads/1369/107e5314-e288-42b0-a602-04ba47fe5e8d/500_artistrsquosillustrationofthisheavyproton-likeparticle..png?10000 https://content.presspage.com/uploads/1369/107e5314-e288-42b0-a602-04ba47fe5e8d/artistrsquosillustrationofthisheavyproton-likeparticle..png?10000
£9.6M SATURN-2 programme launched to deliver the UK’s next generation of nuclear experts /about/news/96m-saturn-2-programme-launched-to-deliver-the-uks-next-generation-of-nuclear-experts/ /about/news/96m-saturn-2-programme-launched-to-deliver-the-uks-next-generation-of-nuclear-experts/738847The University of Manchester, together with six leading UK universities and 22 industry partners, has secured £9.6 million from UK Research and Innovation (UKRI) to launch SATURN-2, a major expansion of the national nuclear doctoral training pipeline that will help deliver the skills required for the UK’s clean energy, security and defence ambitions.

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The University of Manchester, together with six leading UK universities and 22 industry partners, has secured £9.6 million from UK Research and Innovation (UKRI) to launch SATURN-2, a major expansion of the national nuclear doctoral training pipeline that will help deliver the skills required for the UK’s clean energy, security and defence ambitions.

SATURN-2 (Skills and Training Underpinning a Renaissance in Nuclear) builds on the success of the original , doubling its size and introducing expanded training pathways across the entire nuclear fuel cycle. The programme will recruit around 50 PhD/EngD students per year for the next four years, delivering just under half of the 500 high skill nuclear doctoral graduates the UK is estimated to need by 2030.

The programme brings together seven universities: The University of Manchester (lead), The University of Liverpool, Lancaster University, The University of Strathclyde, The University of Sheffield, The University of Leeds, and Bangor University. These universities represent more than 70% of the UK’s nuclear academic community and deliver expertise across the entire nuclear fuel cycle.

Backed by £8 million of industrial co‑investment and £4 million from university partners, SATURN-2 represents one of the most significant UK investments in advanced nuclear skills in over a decade.

The programme also maintains a strong regional base across the North West, North Wales and Scotland, home to the UK’s most concentrated cluster of nuclear industry, research facilities and workforce.

, SATURN CDT Director from The University of Manchester said: “This Doctoral Focal d reflects the success of the original SATURN Centre for Doctoral Training and its important role in supporting the government’s ambitions for Nuclear. Building on that foundation, SATURN-2 will expand the programme significantly, while continuing to deliver world-leading training for the next generation of specialists the UK needs in this sector. We are proud to lead this collaboration with outstanding partners across the UK.”

Meeting critical UK skills needs

The UK Government’s Strategic Defence Review and National Nuclear Strategic Plan for Skills highlight an urgent shortage of high skill nuclear scientists and engineers, with an estimated 120,000 workers needed by the 2030s, including a rapidly depleting cohort of subject matter experts.

SATURN-2 directly addresses this challenge by training specialists across:

  • Nuclear fuel manufacture and performance
  • Reactor science, engineering and operations
  • Decommissioning and waste management
  • Fusion‑fission interfaces
  • Digital engineering, robotics and AI in nuclear contexts

Students will benefit from an enriched training programme including a three‑month residential bootcamp, specialist modules across the partner institutions, international experiences at leading laboratories, and secondments into industry, national labs and government agencies.

Professor Charlotte Deane, Executive Chair at UKRI’s Engineering and Physical Sciences Research Council said: “The UK's nuclear sector is central to our national security, clean energy ambitions and economic future. Meeting those challenges demands a new generation of researchers and innovators with the technical expertise to make a real difference. 

“UKRI doctoral focal awards are a proven way to develop that talent. They bring together academic excellence, industry partnerships and cohort-based learning to give doctoral students the skills and experience to make an immediate impact in the nuclear workforce.  

“These new nuclear focal awards, developed in partnership with government, will continue building the research base that the UK's national security and clean energy future depends on.” 

A proven pipeline into the nuclear workforce

Over 15 years of predecessor CDTs, Nuclear First, Next Generation Nuclear, GREEN and SATURN, the consortium has trained more than 300 doctoral researchers, with exceptionally strong career outcomes.

High‑level destination data shows that:

  • 75% of graduates now work directly in the nuclear industry
  • 18% progressed into education or academia
  • 5% are employed in nuclear‑relevant government roles

These figures demonstrate the CDT’s sustained role as the UK’s most effective route for producing nuclear subject matter experts.

Exceptional industrial engagement

SATURN-2 is supported by 22 industry partners spanning the civil, defence and advanced nuclear sectors, including Rolls Royce, BAE Systems, Sellafield Ltd, the Nuclear Decommissioning Authority, AWE, EDF, UK NNL, Urenco, Framatome, AtkinsRéalis and Rapiscan.

Industrial partners have committed:

  • 48 co‑funded studentships
  • ~£4 million of in‑kind support (supervision, placements, facilities, equipment, training)

Industry demand for SATURN trained researchers continues to rise, demonstrating trust in the consortium’s ability to deliver highly employable graduates ready for the most complex national nuclear challenges.

Supporting additional national doctoral centres

In addition to leading SATURN‑2, The University of Manchester is also a supporting partner in several of the newly funded Centres for Doctoral Training announced alongside SATURN‑2, including:

  • RAPTOR (Radiation Protection, Nuclear Safety and Environmental Sustainability), led by the University of Liverpool
  • DRIVERS (Developing Researchers with an Interdisciplinary Vision for Engineering Reactor Systems), led by Imperial College London
  • PANDA (Programme for Accelerating Nuclear Development and Applications), led by Bangor University

The work reflects the University’s wider role in strengthening the UK’s national nuclear skills pipeline.

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Fri, 13 Mar 2026 12:18:32 +0000 https://content.presspage.com/uploads/1369/e8aaccca-955e-4691-bae1-37ad5a6817fd/500_dsc_2038.jpg?10000 https://content.presspage.com/uploads/1369/e8aaccca-955e-4691-bae1-37ad5a6817fd/dsc_2038.jpg?10000
Carbon-trapping rocks demonstrate Earth’s natural ability to store carbon dioxide /about/news/carbon-trapping-rocks-demonstrate-earths-natural-ability-to-store-carbon-dioxide/ /about/news/carbon-trapping-rocks-demonstrate-earths-natural-ability-to-store-carbon-dioxide/738444Researchers have shed new light on how a unusual rock formation in Oman was created, which could reveal new details about the Earth’s ability to store carbon dioxide (CO2) for millions of years.

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Researchers have shed new light on how a unusual rock formation in Oman was created, which could reveal new details about the Earth’s ability to store carbon dioxide (CO2) for millions of years.

The study, led by Keele University, in collaboration with The University of Manchester and University of Ottawa, looked at geological evidence from Oman to better understand processes that occur in subduction zones - where one of the Earth’s tectonic plates sinks beneath another due to the plates colliding together. Such zones are active around much of the Pacific “Ring of Fire” today.

Subduction zones are key to the global carbon cycle because ocean sediments carried by the sinking plate contain large amounts of CO₂. Scientists have long debated what happens to this carbon after it sinks - some is transported deep into the Earth, while some returns to the atmosphere via volcanic eruptions.

Another possibility is that CO₂ becomes trapped in rocks when carbon-rich fluids react with them, forming minerals known as carbonates, which lock the carbon away for millions of years. These reactions happen tens of kilometres underground, so are difficult to observe and study.

To resolve this, the team analysed halogens - chlorine, bromine and iodine - which were present within individual mineral grains. These elements can leave a fingerprint of the fluid reactions and sources of carbon which formed the carbonate minerals.

Their results, published in , indicated that there were at least two separate events where CO₂ reacted with the rocks. It found that most of the carbonate minerals formed from fluids that match those usually found in subduction zones.

They also calculated that over 90% of the CO₂ in the sinking plate could have been channelled along the plate boundary fault into the shallow mantle and locked away, indicating that carbon sinks in subduction zones are not only real, but could play a significant role in the Earth’s carbon cycle, by offering a way to store huge amounts of CO₂ for millions of years.

Lead author, Dr Elliot Carter, from the School of Life Sciences at Keel University said: “As our climate warms there’s been increasing attention on these strange and enigmatic rocks and what they can tell us about how the Earth moves carbon around and how humans could store it in the future”

“Zooming into chemical differences between different microscopic crystals really gave us the key to unlock the story of these rocks”

“We can now tell that rocks such as those in Oman likely form an important part of Earth’s long-term carbon cycle.”

This research was published in the journal Nature Communications.

Full title: Carbonated mantle peridotites represent a hidden sink for subducted CO2

 DOI:  

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Tue, 10 Mar 2026 11:37:45 +0000 https://content.presspage.com/uploads/1369/63e537e0-17d2-4572-9345-ad53ce414cc0/500_thedigsiteinoman..jpg?10000 https://content.presspage.com/uploads/1369/63e537e0-17d2-4572-9345-ad53ce414cc0/thedigsiteinoman..jpg?10000
Researchers create a never-before-seen molecule and prove its exotic nature with quantum computing /about/news/researchers-create-a-never-before-seen-molecule-and-prove-its-exotic-nature-with-quantum-computing/ /about/news/researchers-create-a-never-before-seen-molecule-and-prove-its-exotic-nature-with-quantum-computing/738101Scientists have created and characterized a molecule unlike any previously known — one whose electrons travel through its structure in a corkscrew-like pattern that fundamentally alters its chemical behavior. 

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An international team of scientists from IBM, The University of Manchester, Oxford University, ETH Zurich, EPFL and the University of Regensburg have created and characterized a molecule unlike any previously known — one whose electrons travel through its structure in a corkscrew-like pattern that fundamentally alters its chemical behavior. 

Published today in , it is the first experimental observation of a half-Möbius electronic topology in a single molecule. To the scientists’ knowledge, a molecule with such topology has never before been synthesized, observed, or even formally predicted. 

Understanding this molecule’s behavior at the electronic structure level required something equally fundamental: a high fidelity quantum computing simulation. The discovery advances science on two fronts. For chemistry, it demonstrates that electronic topology - the property governing how electrons move through a molecule - can be deliberately engineered, not merely found in nature. 

For quantum computing, it is a concrete demonstration of a quantum simulation doing what it was designed to do: representing quantum mechanical behavior directly, at the molecular scale, to produce scientific insight that would otherwise have remained out of reach. 

“First, we designed a molecule we thought could be created, then we built it, and then we validated it and its exotic properties with a quantum computer,” said Alessandro Curioni, IBM Fellow, Vice President, Europe and Africa, and Director of IBM Research Zurich. “This is a leap towards the dream laid out by renowned physicist Richard Feynman decades ago to build a computer that can best simulate quantum physics and a demonstration where, as he said, ‘There’s plenty of room at the bottom.’ The success of this research signals a step towards this vision, opening the door for new ways to explore our world and the matter within it.

, paper co-author, Lecturer in Computational and Theoretical Chemistry at The University of Manchester, added: “Chemistry and solid-state physics advance by finding new ways to control matter. In the second half of the 20th century, substituent effects were very popular. For example, researchers explored how the potency of a drug or the elasticity of a material changes if, for example, a methyl is replaced with chlorine. The turn of the century brought us spintronics, introducing electron spin as a new degree of freedom to play with, and transforming data storage. Today, our work shows that topology can also serve as a switchable degree of freedom, opening a new powerful route for controlling material properties. 

“The non-trivial topology of this molecule, and the exotic behavior of many other systems, arises from interactions between their electrons. Simulating electrons with classical computers is very hard – a decade ago we could exactly model 16 electrons, and today we can go up to 18. Quantum computers are naturally well-suited for this problem because their building blocks – qubits – are quantum objects, which mirror electrons. Using IBM’s quantum computer, we were able to explore 32 electrons. However, the most exciting part is this is just the start. Quantum hardware is advancing rapidly, and the future is quantum.”

A Never-Before-Seen Molecule 

The molecule, with the formula C₁₃Cl₂, was assembled atom-by-atom at IBM from a custom precursor synthesized at Oxford University, with individual atoms removed one at a time using precisely calibrated voltage pulses under ultra-high vacuum at nearabsolute-zero temperatures. 

Experiments with scanning tunneling and atomic force microscopy, both techniques pioneered at IBM, combined with quantum computing to reveal an electronic configuration with no counterpart in chemistry's existing record: an electronic structure that undergoes a 90-degree twist with each circuit, requiring four complete loops to return to the starting phase. 

This half-Möbius topology is qualitatively distinct from any previously known molecule and can be reversibly switched between clockwise-twisted, counterclockwise-twisted and untwisted states — demonstrating that electronic topology is not a property to be discovered, but one that can now be deliberately engineered under specific conditions.

A Disruptive Scientific Tool: Quantum-Centric Supercomputing 

The scientists in this experiment created a molecule that had never existed. Now they had to figure out why it worked, a task which challenged conventional computers. The electrons within C₁₃Cl₂ interact in deeply entangled ways — each influencing all the others simultaneously. Modeling that behavior requires tracking every possible configuration of those interactions at once, requiring computational demands that grow exponentially and can quickly overwhelm classical machines.

Quantum computers are different by nature because they operate according to the same quantum mechanical laws that govern electrons in molecules, and they can represent these systems directly rather than approximate them. They “speak” the same fundamental language as the matter they are built to study and that distinction, once largely theoretical, can now contribute to concrete scientific results.

This capability offers tremendous potential for quantum computers to support realworld experimentation with quantum-centric supercomputing workflows. By integrating quantum processing units (QPUs), CPUs, and GPUs, quantum-centric supercomputing allows complex problems to be broken into parts that are orchestrated and solved according to each system’s strengths — achieving what no single compute paradigm can deliver alone.

Utilizing an IBM quantum computer within such a workflow, the team found helical molecular orbitals for electron attachment, a fingerprint of the half-Möbius topology. Moreover, simulation via quantum computing helped reveal the mechanism behind the formation of the unusual topology: a helical pseudo-Jahn-Teller effect.

This achievement builds on IBM’s long legacy in nanoscale science. The scanning tunneling microscope (STM) was invented at IBM in 1981, for which IBM scientists Gerd Binnig and Heinrich Rohrer were awarded the Nobel Prize in 1986. Its creation enabled researchers to image surfaces atom by atom. In 1989, IBM scientists developed the first reliable method for manipulating individual atoms. Over the past decades, the IBM team has extended these techniques to build and control increasingly exotic molecular structures.

This research was published in the journal Science 

Full title: A molecule with half-Möbius topology

DOI:  

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Thu, 05 Mar 2026 19:01:00 +0000 https://content.presspage.com/uploads/1369/ba02fb27-728a-44b6-a160-14b39cc48a51/500_dysonorbitalforelectronattachmentcalculatedusingquantumhardware.creditibmresearchandtheuniversityofmanchester..png?10000 https://content.presspage.com/uploads/1369/ba02fb27-728a-44b6-a160-14b39cc48a51/dysonorbitalforelectronattachmentcalculatedusingquantumhardware.creditibmresearchandtheuniversityofmanchester..png?10000
How loud is clean energy? Manchester-led study explores potential impact of underwater noise from tidal energy /about/news/how-loud-is-clean-energy-manchester-led-study-explores-potential-impact-of-underwater-noise-from-tidal-energy/ /about/news/how-loud-is-clean-energy-manchester-led-study-explores-potential-impact-of-underwater-noise-from-tidal-energy/737780The University of Manchester will lead a new research project to understand how noise generated by tidal-stream turbines travels through the marine environment and how it may affect marine life, supporting the responsible commercial scaling of tidal energy.

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The University of Manchester will lead a new research project to understand how noise generated by tidal-stream turbines travels through the marine environment and how it may affect marine life, supporting the responsible commercial scaling of tidal energy.

As the UK prepares for a rapid expansion of tidal energy, (not)NOISY (Propagation of NOISe generated by tidal arraYs and its environmental impacts) will develop the first advanced tools capable of predicting the cumulative underwater noise produced by tidal turbine arrays before they are built.

The research will support industry, regulators and policymakers to strengthen the evidence base used in environmental assessments and enable informed, proportionate decision-making as the sector grows.

Tidal energy is emerging as a key part of the UK’s renewable energy mix. Unlike wind and solar power, which depend on weather conditions, tidal power is highly predictable and can deliver a steady, reliable source of energy day in, day out, making it the perfect complement to other renewable energy.

As the sector scales-up and larger turbine arrays, with 10 devices or more, are planned for deployment, understanding their environmental impacts is becoming increasingly important, particularly potential collision risks with marine macro-fauna and underwater noise. Modelling suggests turbine noise could travel up to 8 km through the ocean.

Lead researcher , Research Fellow in the Department of Civil Engineering and Management at The University of Manchester, said: “Tidal stream energy has enormous potential to support the UK’s Net Zero ambitions, but its long-term success depends on our ability to accurately assess and manage environmental impacts, hence accelerating project permitting and licensing.

“Noise generation is one of the biggest uncertainties facing tidal projects today but tools to estimate cumulative acoustic outputs with high confidence do not yet exist. With tidal arrays expected to grow in number and size, we need tools that can predict their cumulative acoustic footprint prior to deployment. (not)NOISY will provide exactly that.”

The research team will develop advanced high-fidelity computer models and AI-assisted rapid tools that closely replicate real world tidal stream site conditions, allowing researchers to quantify how noise from tidal turbines travels through real marine environments. The model will be applied in both near- and far-wake regions, across different turbine types (floating and bottom-fixed) and environmental conditions at four major European sites – EMEC and in Scotland, Raz Blanchard between France and the Channel Islands and Morlais in Wales.

The findings will lead to the development of PyTAI (Python Tidal-Array Induced acoustics), an open-source, AI-driven tool that will enable rapid prediction of tidal turbine noise under a wide range of operating conditions. The tool will support future environmental impact assessments and contribute to the development of evidence-based policy and regulatory guidance.

Dr Ouro added: “By improving confidence in marine noise prediction, we hope this project will help accelerate the next generation of tidal-stream developments, supporting clean energy growth while protecting marine ecosystems, in order to  foster an industry of national importance.”

(not)NOISY is funded by UKRI Engineering and Physical Sciences Research Council Supergen Offshore Renewable Energy Impact hub and brings together a strong international consortium, including three European turbine manufacturers, UK and French tidal project developers, policymakers and academic partners, ensuring close collaboration between research, industry and regulation.

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Tue, 03 Mar 2026 11:06:30 +0000 https://content.presspage.com/uploads/1369/d26839b1-bc8f-4a1c-8df4-2e90a29938d4/500_rogue-wave-copyright-v-sarano.jpg?10000 https://content.presspage.com/uploads/1369/d26839b1-bc8f-4a1c-8df4-2e90a29938d4/rogue-wave-copyright-v-sarano.jpg?10000
University of Manchester to lead accelerated research project tackling violence against women and girls /about/news/university-of-manchester-to-lead-accelerated-research-project-tackling-violence-against-women-and-girls/ /about/news/university-of-manchester-to-lead-accelerated-research-project-tackling-violence-against-women-and-girls/737227An interdisciplinary research team at The University of Manchester have been awarded £625,000 to accelerate the UK’s efforts to prevent and respond to violence against women and girls (VAWG).Content warning: References to sexual violence, domestic abuse, sexual harassment and homicide.

Violence against women and girls (VAWG) remains a widespread and underreported issue across the UK. According to official statistics, more than 200,000 sexual offences were recorded by UK police in England and Wales in 2024/25, and 2.2 million women aged 16+ experienced domestic abuse in the year ending March 2025.

In response to this crisis, – a new project hosted by , and – has been awarded £625,000 from to accelerate national efforts to prevent and respond to VAWG. Bringing together leading researchers, practitioners and policymakers, RISE will feed in to the delivery of the and recent which aim to halve VAWG within a decade.

The project will consist of four team‑led research projects covering primary prevention (working with men and boys), women’s safety in public spaces, management of domestic abuse perpetrators and child-parent homicides. RISE will also provide to enable researchers and practitioners across policing, third sector and policymaking to collaborate and pilot new approaches.

RISE draws on the expertise of and , whose influential research on abuse of women runners was recently cited in Parliament, , a leading authority on domestic abuse and masculinities, and , co‑director of and specialist in crime data analysis.

The project is further strengthened by NSEC and SALIENT Principal Investigator , who will support the team in securing complex multi‑agency research data, and privacy expert and SPRITE+ director, who will lead stakeholder engagement and lead an in-depth evidence review of primary prevention strategies.

More information on RISE

Advice and support

  • (England): 0808 2000 247
  • (England and Wales): 0808 500 2222
  • (Northern Ireland): 0808 802 1414
  • (Scotland): 0800 027 1234

In an emergency call 999. If it’s unsafe to speak and you call from a mobile, press 55 and you will be transferred to a police call handler trained to deal with ‘silent calls’.

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Wed, 25 Feb 2026 14:18:01 +0000 https://content.presspage.com/uploads/1369/073175a3-e1b1-4634-921c-fd315b97b56c/500_artur-rekstad-0tozkpet-i0-unsplash002.jpg?10000 https://content.presspage.com/uploads/1369/073175a3-e1b1-4634-921c-fd315b97b56c/artur-rekstad-0tozkpet-i0-unsplash002.jpg?10000