The world’s first roadmap to a circular space economy

From reusable rockets to space stations that could one day recycle floating debris into new materials, a first-of-its-kind study from the University of Surrey and the UK Space Agency sets out the world’s first roadmap to a circular space economy.

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Published in Chem Circularity, the research investigates how circular economy principles could transform the way the space sector designs, builds and operates missions both on Earth and beyond. It identifies where reusability, repair and in-orbit recycling could replace today’s single-use practices – and argues that, in space, in-orbit repair and recycling must become a priority rather than a last resort.

With more than 8,000 satellites already orbiting Earth and thousands more planned, demand for critical materials such as titanium, lithium and rare earth elements is expected to soar unless the sector adopts more sustainable approaches.

The paper also highlights how advances in chemistry, materials science and artificial intelligence could make this circular future possible – from materials that can repair themselves to digital twin simulations that allow for less physical testing.

Each rocket launch sends tonnes of valuable materials into space that are never recovered. To make the space economy truly sustainable, we need to build circular thinking into missions from the very start – from how we design and manufacture spacecraft to how we operate and retire them. That means developing systems that can be refuelled, repaired or reconfigured in orbit, and materials that can be recovered and recycled rather than lost. Professor Jin Xuan, Associate Dean (Research and Innovation)

Our goal was to understand where circular principles make the biggest impact. It’s clear there are big opportunities to reuse and recover materials efficiently. Other industries have already set the blueprint for circular design, and now it’s time to bring that thinking into this multi-billion-pound space economy. Zhilin yang, PhD researcher in Circular Economy at the University of Surrey, and lead author of the study

Looking to other industries already tackling similar sustainability challenges, the paper highlights valuable lessons that could be applied to the space sector. The electronics industry, for example, has developed ways to recover precious metals from discarded devices, while the automotive sector has shown how repairing and remanufacturing components can keep vehicles on the road for longer and cut waste. Adapting these approaches for the extreme conditions of space could prove vital for creating spacecraft that last longer, waste less and support a more resilient circular space economy.

The space sector is at a turning point. For decades, we’ve relied on a one-way flow of materials from Earth to orbit – but that model isn’t sustainable. We need to rethink how we use what’s already out there. The same debris that threatens satellites today could become the raw material for tomorrow’s missions – recycled into new components, repurposed for refuelling or even 3D-printed into replacement parts. Advances in AI and smarter design are already showing how we can turn waste into opportunity and make space exploration more sustainable. Professor Adam Amara, Head of School of Mathematics and Physics

Building on Surrey’s track record in sustainable space engineering – including the RemoveDEBRIS mission, one of the world’s first successful in-orbit demonstrations of capturing space debris – the research will inform the work of the newly launched Surrey Space Institute. The Institute brings together a team of experts and partners across engineering, materials science, AI, law and bioscience to develop technologies and missions that keep space resilient, safeguard Earth’s resources and train the next generation of space innovators.

The study – funded by the Engineering and Physical Sciences Research Council (EPSRC), the Leverhulme Trust and the Surrey–Adelaide Partnership Fund – marks the first step in a longer-term programme to develop the technologies and governance frameworks needed for a truly circular space economy.

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Notes to editors