By

Principal investigator
Daniel Scheeres

Funding
NASA

Collaboration + support
Ann and H.J. Smead Department of Aerospace Engineering Sciences; University of Arizona; NASA Goddard Space Flight Center; Lockheed Martin

Asteroid Bennu

 Bennu ~510m; Empire State Building 443m; Eiffel Tower 324m

OSIRIS rocketResearchers at 񱦵 have gotten front-row seats to one of theclosest encounters with an asteroid in history.

On Dec. 4, 2018, NASA’s Origins, Spectral Interpretation, ResourceIdentification, Security-Regolith Explorer (OSIRIS-REx) spacecraftzipped to within 4.5 miles of the asteroid Bennu. This space rock has anorbit that carries it relatively near to Earth about once every six years.

It was the first in a series of planned meet-ups between OSIRIS-RExand Bennu, and good practice for 2020. Next summer, the spacecraftwill dip just above the asteroid’s surface, using its retractable arm tosnag material from the top and then bring it back to Earth.

񱦵’s Daniel Scheeres leads the radio science team for OSIRIS-REx.The overall mission is led by the University of Arizona. He said it’san unprecedented opportunity to get a zoomed-in look at a class ofmysterious solar system residents.

“When you’re going to a new world, you have some idea of what itmight look like,” said Scheeres, a Distinguished Professor in the Annand H.J. Smead Department of Aerospace Engineering Sciences. “Thenyou actually go there, and you can start comparing what youthought itmight look like versus reality.”

In particular, his group has an eye on a simple-seeming but importantnumber: Bennu’s mass.

Scheeres and his colleagues are using OSIRIS-REx’s navigationalinstruments to measure the minute pull that Bennu exerts on thespacecraft—information that then allows them to map out the gravity atits surface.

Scientists want to gather that kind of data for many reasons, saidJay McMahon, an assistant professor in aerospace engineering at񱦵.

Asteroids, for example, provide researchers with a rare window to lookback at the beginnings of the solar system.

“One of the big draws for asteroids is that they’re leftovers from theformation of the solar system,” said McMahon, a co-investigator onthe mission. “Bennu is a building block of the planets that didn’t endup in a planet.”

The results have already started to roll in. In March 2019, theresearchers released their first estimates for the mass of Bennu:a respectable 73 billion kilograms.

They’ve also begun to get a closer look at the physics of this body—physics that would boggle most earthlings.

“Bennu spins fast enough to create a competition between the gravitythat’s holding you down and the centrifugal acceleration, which is tryingto throw you off,” Scheeres said.

And he isn’t stopping at Bennu, either. In June 2019, NASA picked amission led by Scheeres, called Janus: Reconnaissance Missions toBinary Asteroids, as a finalist for its SIMPLEx small satellite program.

If the mission gets the final green light, Janus will send twin spacecraftto rendezvous with binary asteroids. Scientists have yet to observe suchobjects, in which two asteroids revolve around each other, up close.

“There are many theories of how binary asteroids form, but we haven’thad the proper measurements to sort through them all and see whichis correct,” Scheeres said. “The Janus mission will do this and also helpus better understand how primitive bodies in the solar systemhaveformed and evolved over time.”

In other words, the solar system’s asteroids are becoming a little lesspuzzling thanks to 񱦵.