More than meets the eye: astronomers dig deep to find tiny but dangerous space debris
In a new study, published in the Journal of the Astronautical Sciences, Warwick researchers have led an international effort to uncover some of the faintest debris in geosynchronous orbit that have ever been observed, finding fragments as small as 5 cm in size and obtaining valuable data for characterising their behaviour.
“Pieces of space junk can be moving very quickly relative to one another, as much as several kilometres every second,” explained lead author, Dr James Blake, Research Fellow at Warwick’s Centre for Space Domain Awareness. “The energies involved are really high, and even small debris can cause a lot of damage to very expensive satellites, so small things really matter.”
Geosynchronous orbit is a vantage point roughly 36,000 km above the Earth’s equator where satellites can orbit in synchrony with the rotation of the planet. Satellites orbiting in the unique geostationary belt support a wide range of services from communications and broadcasting to weather and environmental monitoring.
Dr Blake said: “Debris in the neighbourhood of the geostationary belt is particularly concerning. It’s very far away, well above the Earth’s atmosphere, so small objects tend to be incredibly faint and difficult to detect, and any debris that’s generated will stick around indefinitely.”
"The debris in geosynchronous orbit is a potential minefield,” added co-author and space consultant Dr Stuart Eves, SJE Space Ltd. “No-one in their right mind would enter a terrestrial minefield without a mine detector. Similarly, no-one in their right mind should launch a satellite to GEO without an adequate debris survey."
Debris surveys for geostationary orbit (GEO) tend to target a zone shaped like a Hula Hoops crisp surrounding the main orbit, to search for drifting abandoned satellites and uncontrolled debris. The team re-examined an archival dataset from a previous survey of GEO debris, undertaken with the 2.54 m Isaac Newton Telescope (INT) in La Palma, Canary Islands.
By applying newly developed algorithms for processing the images, the team were able to detect very faint targets (some of the faintest debris ever detected) and characterise their behaviour by examining light curves, finding many to be tumbling through space.
To find these faint targets, the team used a blind stacking technique, uncovering 25 detections previously missed by the original analysis. As co-author Dr Ben Cooke, Research Fellow at the University of Warwick, explains: “The blind stacking technique is a very powerful method for improving the sensitivity limit of astronomical datasets. It involves testing many potential paths in an image sequence along which hidden targets might be moving and stacking the images to help bring those targets above the noise floor. This project shows a successful, real-world application of the method - any dataset containing linearly moving targets is an applicable use-case.”
Accounting for the new detections, nearly 80% of the faint objects found in this study were not previously documented (i.e. do not appear in publicly available catalogues), highlighting the need for scientifically driven surveys. The team are now looking to broaden their search, harnessing observations from other telescopes across the globe.
Co-author Prof Will Feline, Senior Principal Scientist at the Defence Science and Technology Laboratory (UK), said: “Following the original survey, the team sought to expand its geographical coverage. This was achieved by using large telescopes in Australia and Japan, in collaboration with the Australian National University and the Japan Aerospace Exploration Agency (JAXA), who brought their considerable technical expertise to the project.
“This really highlights the importance of multinational collaboration for solving global problems such as space domain awareness, but also the advantages of leveraging the UK’s world-class academic expertise for the benefit of UK defence.”
Dr Blake concluded: “There are a finite number of orbital slots in the GEO belt, so it’s important that we know how much debris is out there, how it behaves, and what risks are posed to the active satellites we rely on. Surveys for faint debris help us build a clearer picture.”
ENDS
Notes to Editors
The paper ‘DebrisWatch II: Digging Deeper for Geosynchronous Debris’ is published in the Journal of the Astronautical Sciences: https://doi.org/10.1007/s40295-026-00602-1
The researchers received funding from the Science Technology and Facilities Council.
Size estimates for debris were calculated under standard assumptions.
Image - The GEO Polar images are generated from a vantage point above the north pole, showing the concentrations of satellites in LEO and in the ring-like geosynchronous region. Credit: NASA/ODPO
GIF – Simulation demonstrating the ability of image stacking to bring faint signals up above the noise floor. Credit: Dr Ben Cooke / University of Warwick
Graph – (Top) Histogram of brightness measurements, with new (very faint) detections highlighted in blue. (Bottom) A ~25 cm fragment detected by the original single-image approach, alongside a ~5 cm fragment previously missed, but detected by the blind stacking technique. Credit: Dr James Blake / University of Warwick
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08 July 2026