Nearly two years ago, NASA made history when its OSIRIS-REx spacecraft briefly to collect a regolith sample from the surface of the asteroid. While the mission won’t return to Earth , NASA shared new information about the celestial body. In an published this week (via ), the agency revealed OSIRIS-REx would have sunk into Bennu had the spacecraft not immediately fired its thrusters after touching the asteroid's surface.
"It turns out that the particles making up Bennu’s exterior are so loosely packed and lightly bound to each other that if a person were to step onto Bennu they would feel very little resistance, as if stepping into a pit of plastic balls that are popular play areas for kids," NASA said.
#OSIRISREx data gathered during sample collection show that asteroid Bennu's exterior is made up of loosely packed & lightly bound rock. So, standing on its surface would feel like being in a plastic ball pit.
Ready, set, jump! https://t.co/xX75KDjAFW pic.twitter.com/P0xxIte2jN
— NASA 360 (@NASA360) July 8, 2022
That’s not what scientists thought they would find on Bennu. Observing the asteroid from Earth, the expectation was that its surface would be covered in smooth, sandy beach-like material. Bennu’s reaction to OSIRIS-REx’s touchdown also had scientists puzzled. After briefly interacting with the asteroid, the spacecraft left a 26-foot (8-meter) wide crater. In lab testing, the pickup procedure “barely made a divot.”
After analyzing data from the spacecraft, they found it encountered the same amount of resistance a person on Earth would feel while squeezing the plunger on a French press coffee carafe. “By the time we fired our thrusters to leave the surface, we were still plunging into the asteroid,” said Ron Ballouz, a scientist with the OSIRIS-REx team.
According to NASA, its findings on Bennu could help scientists better interpret remote observations of other asteroids. In turn, that could help the agency design future asteroid missions. “I think we’re still at the beginning of understanding what these bodies are, because they behave in very counterintuitive ways,” said OSIRIS-REx team member Patrick Michel.