When Oumuamua, the first interstellar object ever observed passing through the Solar System, was discovered in 2017, it exhibited some unexpected properties that left astronomers scratching their heads. Its elongated shape, lack of a coma, and the fact that it changed its trajectory were all surprising, leading to several competing theories about its origin: was it a hydrogen iceberg exhibiting outgassing, or maybe an extraterrestrial solar sail (sorry folks, not likely) on a deep-space journey? We may never know the answer, because Oumuamua was moving too fast, and was observed too late, to get a good look.
It may be too late for Oumuamua, but we could be ready for the next strange interstellar visitor if we wanted to. A spacecraft could be designed and built to catch such an object at a moment’s notice. The idea of an interstellar interceptor like this has been floated by various experts, and funding to study such a concept has even been granted through NASA’s Innovative Advanced Concepts (NIAC) program. But how exactly would such an interceptor work?
A new paper released on ArXiv on June 27th explores one possible mission design. Derived from the NIAC study, the proposal suggests combining solar sail technology with the ability to miniaturize space probes to small, lightweight sizes.
Missions like JAXA’s IKAROS probe to Venus and the Planetary Society’s ongoing LightSail 2 project in Earth orbit have shown that solar sails, which use photons from the sun to accelerate, are entirely feasible propulsion systems. Similarly, the successful use of CubeSats on interplanetary missions was demonstrated by the Jet Propulsion Laboratory in 2018. They sent two CubeSats, named Mars Cube One (MarCO-a and MarCO-b), to accompany the InSight lander on its journey to the red planet. The CubeSats worked like a charm.
When combined, solar sails and CubeSats could be a powerful tool for exploration.
To intercept an interstellar object, the paper proposes that a solar-sailing CubeSat could be launched ahead of time, ‘parking’ in an orbit around the Sun where it would wait quietly for the discovery of the next interesting object worth chasing. A fast response vehicle like this would allows for various mission designs. A five-year mission, for example, could easily catch up and study an interstellar object, beaming back to Earth the kind of data that we failed to get from Oumuamua. On the other hand, a similar spacecraft could even carry out a sample return mission, if given a longer timeframe of ten years.
One of the major engineering challenges for such a mission concerns the solar sail’s ability to manage heat. The interceptor would have to travel much closer to the Sun than any previous solar sail tests, which usually use aluminum coated with Kapton. The properties of this material might enable it to survive within 0.15 AU of the Sun without melting, but careful consideration will have to be given to shielding the control mechanisms and other spacecraft systems without adding too much to the spacecraft’s mass. Too heavy, and the sail won’t be able to catch up with the target.
The value of an interceptor spacecraft like this is pretty clear. Even though we’ve only seen two interstellar objects so far, they are probably passing by all the time. Better telescopes coming online this decade will help us find them, but they move fast, and don’t stay for long. If we want to study an interstellar object up close, we’re going to have to be ready for it, and a fast response interceptor spacecraft is likely our best chance at success.
Darren Garber, Louis D. Friedman, Artur Davoyan, Slava G. Turyshev, Nahum Melamed, John McVey, and Todd F. Sheerin, “A Fast Response Mission to Rendezvous with an Interstellar Object.” ArXiv preprint.
Featured Image Credit: John Ballentine.