Meet REMORA: The autonomous space fleet built to tag and track asteroids

To truly understand what an asteroid is made of, we need to send a probe to it. Remote sensing from ground-based telescopes, or even orbiting observatories, can only do so much. A new white paper submitted to the U.K. Space Agency’s 2035 Space Frontiers program (available on the arXiv preprint server) pitches just such a mission architecture. Called the REndezvous Mission for Orbital Reconstruction of Asteroids (REMORA), the plan calls for a swarm of autonomous CubeSats to tag, track and characterize multiple near-Earth asteroids.

The United Kingdom itself is in a bit of a weird place when it comes to asteroid science. It has some of the world’s best researchers, who have contributed to projects like the Double Asteroid Redirection Test (DART) and OSIRIS-REx’s sample return mission to the asteroid Bennu. However, it lacks a dedicated domestic funding stream to launch its own asteroid exploration missions. Obviously, the white paper’s authors, such as Stefania Soldini of the University of Liverpool, have a vested interest in seeing such a domestic funding pipeline develop—but they do have a point.

REMORA hopes to solve that problem. Billed at an extremely low €50 million Mini-F-class mission budget, this mission would develop a fleet of six CubeSats that would hitch a ride to known near-Earth asteroids to characterize them. Named after the famous remoras that attach themselves to sharks and have a symbiotic relationship with them, the plan would be for each individual CubeSat to attach to, or closely orbit, an individual asteroid to study it in a detail far beyond what remote sensing allows.

Managing this would typically require a whole fleet of operators back on Earth—and blow the modest budget completely out of the water. To alleviate that burden, the team is working on software they call Near-Earth Asteroid Regions (NEAR), which is designed to calculate fuel-minimal reserves on the fly, allowing the tiny satellites to navigate near an asteroid without requiring direct operator input. That suite of software is broken up into several components still under development, including dynNEAR for dynamic modeling and goNEAR for pathfinding.

But software is only useful if it has hardware to run on, and that is where the white paper points out another advantage the U.K. has, specifically at the lead author’s home institution, the University of Liverpool: the Zero-G Astrolab. Boasting the “flattest floor in the U.K.,” the lab allows for hardware-in-the-loop testing with physical prototypes floating across the epoxy air-bearing system that makes up that floor.

But the University of Liverpool isn’t the only advantage the U.K. has in space. Surrey has famously developed a small-satellite industry cluster, including Surrey Satellite Technology Ltd. (SSTL). The white paper pushes for a Phase 0 pilot study to help integrate these scientific missions into the payload of future SSTL missions as a proof of concept.

The timing couldn’t be better—in 2029, the 350-meter-wide (1,150-foot-wide) asteroid Apophis will pass closer to Earth than some of our geosynchronous communications satellites, and will be visible to the naked eye in part of the U.K. That year is also the U.N.’s International Year of Asteroid Awareness and Planetary Defense, and one weak point we still have in our planetary defense capabilities is the ability to catch asteroids coming from the sunward direction, like the one that exploded over Chelyabinsk, Russia, in 2013.

REMORA is designed specifically to solve problems like that blind spot. But given the rough budgetary constraint the U.K. is currently under, it seems like a long shot that such a mission architecture would be funded anytime soon. That being said, the U.K.’s space agency isn’t the only organization that could benefit from the country’s infrastructure—so maybe this mission architecture is worth a look by other private and public organizations alike.

Who’s behind this story?

Lisa Lock

BA art history, MA material culture. Former museum editor, paramedic, and transplant coordinator. Editing for Science X since 2021.

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Andrew Zinin

Master’s in physics with research experience. Long-time science news enthusiast. Plays key role in Science X’s editorial success.

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