-With images-
Astronomers at Durham University have made a major development in our understanding of how galaxies formed and evolved in the early Universe.
Using powerful new observations, the team has discovered the most distant example ever found of a compact, star-forming structure at the heart of a galaxy, dating back more than nine billion years.
The research reveals clear evidence of a ‘nuclear disc’ (a dense, rotating disc of stars at the very centre of a galaxy) forming at a time when the Universe was still relatively young.
Nuclear discs are common in nearby, mature galaxies, but until now they had never been observed so far back in cosmic history. This discovery shows that galaxies were already developing complex internal structures much earlier than scientists had assumed.
The Durham-led team made the discovery using data from the James Webb Space Telescope, whose unprecedented sensitivity and sharp vision allow astronomers to study distant galaxies in extraordinary detail.
The galaxy they studied is seen as it was just 4.5 billion years after the Big Bang. At its centre, the researchers identified a nuclear disc that is actively forming new stars and is still growing.
Crucially, the nuclear disc appears to have been built by a long, bar-shaped structure of stars stretching across the galaxy. These bars are a familiar feature of many present-day spiral galaxies and act like cosmic engines, driving gas and stars towards the centre and helping new structures to form.
While previous studies had shown that bars themselves can form early, there was no direct proof that they were already reshaping galaxies at this stage in the Universe’s history. This research provides that missing evidence.
Lead author of the study, Zoe Le Conte from Durham University, said: “This is a remarkable and unexpected discovery that will make astronomers revisit the idea of galaxy evolution and the influence of stellar bars in the early Universe.
“The extraordinary images and novel results from James Webb Space Telescope continue to reveal that mature galaxies exist much earlier than we previously thought.”
Despite its great distance, the newly discovered nuclear disc already shares many of the same properties as nuclear discs found in nearby galaxies today.
It is compact, rich in young stars, and shows clear signs of organised growth. This suggests that galaxies did not slowly drift into their present-day forms, but instead matured rapidly, following similar evolutionary pathways over billions of years.
The findings challenge long-standing ideas about galaxy evolution and point to a much more active and structured early Universe. They also have important implications beyond galaxy formation.
Nuclear discs are thought to act as reservoirs of gas that can eventually feed the supermassive black holes found at the centres of most galaxies, meaning this work could also help scientists better understand how black holes grew during the peak era of cosmic activity.
The research team now plans to follow up this discovery with further observations to study how stars and gas move within the galaxy. These future studies will help confirm exactly how the nuclear disc formed and how efficiently the bar is driving material towards the centre.
ENDS
Media Information
Zoe Le Conte from Durham University is available for interview and can be contacted on zoe.a.le-conte@durham.ac.uk .
Alternatively, please contact Durham University Communications Office for interview requests on communications.team@durham.ac.uk or +44 (0)191 334 8623.
Source
‘A nuclear disc at Cosmic Noon: evidence of early bar-driven galaxy evolution’, (2026), Z. A. Le Conte et.al. MNRAS .
https://academic.oup.com/mnras/article-lookup/doi/10.1093/mnras/stag1122
An embargoed copy of the paper is available from Durham University Communications Office. Please email communications.team@durham.ac.uk .
Graphics
Associated images are available via the following link: https://www.dropbox.com/scl/fo/r0f0unoyns6dyl2vptllp/AEk66z9J_rhBmFmGasnNdZY?rlkey=4cyt0u0f1xsaxuvwqznvdyxj4&st=t00n1e0n&dl=0
Image captions
Picture1: Poster child image of a barred galaxy, NGC 1097, with a nuclear disc in the local Universe. Credit: https://www.eso.org/public/images/eso0438d/
Picture2: An RGB image of the nuclear disc, barred galaxy CEERS4031.
Picture3: Residual image of the distant galaxy, where a model has been subtracted from the original image, and unmodelled stellar structures are revealed. Black is excess light (i.e., light emitted by stars), and white is a light deficit. The nuclear disc is outlined, and prominent nuclear spiral arms are unveiled.
About Durham University
Durham University is a globally outstanding centre of teaching and research based in historic Durham City in the UK.
We are a collegiate university committed to inspiring our people to do outstanding things at Durham and in the world.
We conduct research that improves lives globally and we are ranked as a world top 100 university with an international reputation in research and education (QS World University Rankings 2026).
We are a member of the Russell Group of leading research-intensive UK universities, The Times and Sunday Times UK University of the Year 2026, and ranked in the top five in major UK university rankings (The Times and The Sunday Times Good University Guide and the Guardian University Guide).
For more information about Durham University visit: www.durham.ac.uk/about/
END OF MEDIA RELEASE – issued by Durham University Communications Office.
15-Jul-2026