The Asteroid Bennu Keeps Spinning Faster and Scientists Aren't Sure Why

The OSIRIS-REx spacecraft's views over asteroid Bennu's north pole, during the probe's early reconnaissance on Dec. 4, 2018.
The OSIRIS-REx spacecraft's views over asteroid Bennu's north pole, during the probe's early reconnaissance on Dec. 4, 2018. (Image credit: NASA/Goddard/University of Arizona)

On a distant space rock being explored by a NASA probe, days are slowly shortening — and scientists are still trying to figure out why.

Right now, the asteroid known as Bennu is spinning once every 4.3 hours. But scientists working on NASA's OSIRIS-REx mission to the space rock have used data gathered before the probe's arrival to calculate that Bennu's rotation rate is speeding up over time — by about 1 second each century.

"As it speeds up, things ought to change, and so we're going to be looking for those things and detecting this speed up gives us some clues as to the kinds of things we should be looking for," Mike Nolan, lead author on the new research and a geophysicist at the Lunar and Planetary Laboratory at the University of Arizona, who is also head of the OSIRIS-REx mission's science team, said in a statement released by the American Geophysical Union, which published the new research. "We should be looking for evidence that something was different in the fairly recent past and it's conceivable things may be changing as we go."

Related: OSIRIS-REx: NASA's Asteroid Sample-Return Mission in Pictures

The new research, despite the ties to the OSIRIS-REx mission, isn't based on measurements from that probe; instead, it looks at data collected by two ground-based telescopes between 1999 and 2005 and by the Hubble Space Telescope in 2012. That last data caught scientists' eyes because it didn't line up with predictions astronomers had calculated with the ground-based data.

"You couldn't make all three of them fit quite right," Nolan said. "That was when we came up with this idea that it had to be accelerating."

It's not an unknown phenomenon, but it is rare, and scientists only confirmed their first example of an asteroid's rotation speeding up in 2007. Even at Bennu, the observations leave the mystery of what's causing it.

One possible explanation is that material moving around on the surface of Bennu or leaving the asteroid entirely could be allowing the rotation rate to speed up. The other explanation is more complicated, the Yarkovsky–O'Keefe–Radzievskii–Paddack (YORP) effect. That effect is caused by sunlight bouncing off the asteroid and slightly tweaking the spin rate faster or slower depending on the shape of the object. For particularly weak asteroids, the YORP effect can actually tear space rocks apart.

The scientists behind the new research suspect it's the YORP effect that Bennu is experiencing. And over the course of the next two years, OSIRIS-REx will provide more data, including detailed boulder analysis and gravitational measurements. Scientists can use those observations to confirm what's going on at Bennu and pin down local YORP levels.

Those numbers can also help scientists understand the behavior of other asteroids, ones that will never see a dedicated spacecraft.

The research is described in a paper published Jan. 31 in the journal Geophysical Research Letters.

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Meghan Bartels
Senior Writer

Meghan is a senior writer at Space.com and has more than five years' experience as a science journalist based in New York City. She joined Space.com in July 2018, with previous writing published in outlets including Newsweek and Audubon. Meghan earned an MA in science journalism from New York University and a BA in classics from Georgetown University, and in her free time she enjoys reading and visiting museums. Follow her on Twitter at @meghanbartels.