From afar, one asteroid looks much like another, until comparing them directly. Checking the well-known scale chart prepared by the Planetary Society of all asteroid and comets so far surveyed by spacecraft and the larger Didymos asteroid would form a modest dot, with its smaller moonlet struggling to make a single pixel.
Didymos itself is just 780 m across – smaller than any asteroid visited by a probe other than the 350-m diameter Itokawa rubble pile visited by Japan’s first Hayabusa spacecraft and the 500 m-diameter Bennu, around which NASA’s Osiris-REx mission is currently in orbit.
That leaves Didymos’s orbiting moonlet ‘Didymoon’ as the smallest of all asteroids scheduled for robotic inspection, at just 160 m across.
“Didymoon’s miniscule size really becomes clear when you look at other asteroids,” comments Hera’s lead scientist Patrick Michel, CNRS Director of Research of France’s Côte d’Azur Observatory.
Patrick also serves as co-investigator and interdisciplinary scientist on Japan’s Hayabusa2 mission to the Ryugu asteroid, which is about 1 km in diameter: “Hayabusa2 images show a large boulder near the north pole of Ryugu – and that single boulder is about the same size as Didymoon in its entirety.”
Its diminutive size was the reason Didymoon was chosen for a pioneering planetary defence experiment. In 2022, NASA’s DART spacecraft will impact Didymoon in an attempt to change its orbit around its larger twin, to test the feasibility of asteroid deflection.
“This isn’t the first spacecraft impact into a planetary body,” adds Patrick, “NASA’s Deep Impact crashed into comet Tempel 1 in 2005, but not to try and deflect it, instead it was to expose subsurface material – the 6-km diameter body was much too large. But Didymoon is small enough, and in a tight enough 12-hour orbit around its parent, that its orbital period can indeed be shifted in a measurable way.”
After the impact, Hera will survey the Didymos asteroids in 2026 to gather key information that will not be available from Earth-based observations, including Didymoon’s mass, its surface properties and the shape of DART’s crater.
“This will give us a good estimate of the impact’s momentum transfer, and hence its efficiency as a deflection technique,” explains ESA’s Hera project scientist, Michael Küppers. “These are fundamental parameters to enable the validation of numerical impact models necessary to design future deflection missions. We will better understand whether this technique can be used even for larger asteroids, giving us certainty we could protect our home planet if needed.”
Didymoon is very relevant for such testing as it is in the riskiest class of near-Earth asteroids because of its size: larger bodies can more easily be tracked, smaller bodies will burn up or do limited damage, while a Didymoon-sized impactor could devastate an entire region of our planet.
The Didymos system is also attractive in terms of bonus science, offering insight into the formation of the binaries that make up around 15% of known asteroids.
“Didymos is spinning very swiftly, rotating once every two hours,” says Patrick. “Around its equator, its weak pull of gravity could be overcome by centrifugal force, potentially leading to material rising from the surface – the leading theory of where Didymoon came from. So landing on the equator would be impossible; you would have to touch down near its poles instead.
“Didymoon’s small size means we know little about it, but we assume it would be spin-locked around its parent like Earth’s moon, implying a slower spin equal to its orbital period. The plan is to land at least one CubeSat there, although it will require precise navigation to achieve this. The asteroid will have something like one millionth of Earth’s gravity, with an estimated escape velocity of just 6 cm per second, so one danger might be bouncing back out to space.”
Patrick suggests Didymoon-class objects may additionally prove optimal for planned asteroid mining: larger bodies are comparatively rarer, while their smaller equivalents are more prone to fast spinning – caused by gradual warming due to sunlight.
Hera is currently under study to be presented for approval by ESA’s Space19+ Council meeting of European space ministers. It is planned for launch in 2023.
Hera would be ESA’s next mission to a small body after the Rosetta comet-chaser, benefiting from the expertise acquired during that 12-year mission. Long-term planning is crucial to realise future missions, and to ensure the continued development of innovative technology, inspiring new generations of European scientists and engineers.
Science is everywhere at ESA. As well as exploring the Universe and answering the big questions about our place in space we develop the satellites, rockets and technologies to get there. Science also helps us to care for our home planet. All this week we’re highlighting different aspects of science at ESA. Join the conversation with #ScienceAtESA.