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Three Oxford researchers have been selected for the inaugural Royal Society Faraday Discovery Fellowships – major long-term awards for outstanding mid-career research leaders in the UK. Just seven academics were chosen from over 600 applications.

The Faraday Discovery Fellowships are prestigious long-term awards that support the most talented mid-career Science, Technology, Engineering and Mathematics (STEM) researchers. Funded by the Department of Science, Innovation and Technology, the programme provides grants of up to £8 million over 10 years to support the development of world-leading research groups in the UK.

 

Professor Andrew Goodwin, Department of Chemistry

Professor Goodwin's group focuses on using disorder as a design strategy for solid materials. 'In many materials, disorder isn't random; it follows hidden patterns that can actually enhance performance,' he said. 'We see this in systems like batteries, magnets, and even natural materials such as shells.'

Professor Andrew GoodwinProfessor Andrew Goodwin

'I am thrilled and honoured to receive this prestigious grant, which very much builds on the achievements, creativity, and insight of the many talented students, postdocs, and collaborators with whom I have worked over the years. This a truly precious opportunity to tackle some very deep questions in our field.'

His Faraday project will explore materials with "responsive disorder" – where the disorder changes when triggered by heat, pressure, or electricity. 'Many advanced technologies rely on materials that can switch between different states,' he said. 'While traditional materials switch states through changes in crystal structure, disordered materials must follow different rules – offering new possibilities for transformation. We will study several types of disorder found in things such as glasses and polymers, with potential applications in areas like computing. Working with a visual artist, we will also explore new ways of representing these different states.'

 

Professor Andrea Vedaldi, Department of Engineering Science

Professor Vedaldi will focus on Spatial AI, creating a foundation for future AIs that can reason spatially to solve challenging problems.

Professor Andrea VedaldiProfessor Andrea Vedaldi'Even modern AIs, such as chatbots, have only a limited grasp of what things are and how they work in the real world,' Professor Vedaldi explained. 'This limitation leads to hallucinations, where machines assume impossible events could occur, and hinders applications requiring sophisticated spatial reasoning, such as technical design.' His Faraday project will develop Spatial AI that allows machines to predict the consequences of actions in the physical world and use intuition to solve spatial tasks.

'Over time, these machines will also apply mathematics and physics principles to automatically design new structures and machines in response to user requests, potentially revolutionising engineering,' he added. 'Combined with powerful language models, such AIs will be able to reason, act, and create in the physical world – much like we humans can.'

Oxford and its Visual Geometry Group, which I co-lead, have been at the forefront of machine learning and computer vision research for more than three decades. This fellowship offers unique long-term support and will enable us to sustain and expand our impact over the next ten years. I am grateful and honoured that my project was selected by the Royal Society and I look forward to beginning this new journey.

 

Also recognised was Professor Timothy Behrens from the Nuffield Department of Clinical Neurosciences (Fellowship held jointly between Oxford and UCL). Professor Behrens studies complex human behaviours like reasoning and planning. 'To plan effectively, we need to know the relationships between objects and events in the world – we need a model of the world inside our brains,' he said. 'With the Faraday grant, we will try to find out what this model looks like, in terms of the neurons in our brains and the connections between them.'

Sir Adrian Smith, President of the Royal Society, said: 'This exciting first cohort of Royal Society Faraday Discovery Fellowship fellows are using cutting-edge techniques to explore questions at the frontiers of human knowledge...These 10-year fellowships give researchers space to pursue new knowledge, build their research groups and develop close collaborations around the world that will ensure the UK continues to develop and attract the next generation of scientific talent and bring benefits to the whole country.'

Lord Vallance, UK Science Minister, said: 'Turbo-charging our world-class institutions with the very best research talent will be critical to unlocking breakthroughs that could help protect our food chains, put AI to work in the economy, and tackle climate change. That's why DSIT has backed the Royal Society with £250 million in long-term funding to support the work of mid-career researchers who are at the top of their game.'

Further information about the Faraday Discovery Fellowships and the 2026 call can be found on the Royal Society website.

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