Scientists peer inside an asteroid

Date:
October 8, 2020
Source:
University of Colorado at Boulder
Summary:
New findings from NASA's OSIRIS-REx mission suggest that the
interior of the asteroid Bennu could be weaker and less dense than
its outer layers - - like a cre`me-filled chocolate egg flying
though space.



FULL STORY ==========================================================================
New findings from NASA's OSIRIS-REx mission suggest that the interior of
the asteroid Bennu could be weaker and less dense than its outer layers --
like a cre`me-filled chocolate egg flying though space.


==========================================================================
The results appear in a study published today in the journal Science
Advances and led by the University of Colorado Boulder's OSIRIS-REx team, including professors Daniel Scheeres and Jay McMahon. The findings could
give scientists new insights into the evolution of the solar system's
asteroids -- how bodies like Bennu transform over millions of years
or more.

OSIRIS-REx rendezvoused with Bennu, an asteroid orbiting the sun more than
200 million miles from Earth, in late 2018. Since then, the spacecraft,
built by Colorado-based Lockheed Martin, has studied the object in more
detail than any other asteroid in the history of space exploration.

So far, however, one question has remained elusive: What's Bennu like
on the inside? Scheeres, McMahon and their colleagues on the mission's
radio science team now think that they have an answer -- or at least part
of one. Using OSIRIS-REx's own navigational instruments and other tools,
the group spent nearly two years mapping out the ebbs and flows of Bennu's gravity field. Think of it like taking an X-ray of a chunk of space debris
with an average width about the height of the Empire State Building.

"If you can measure the gravity field with enough precision, that places
hard constraints on where the mass is located, even if you can't see it directly," said Andrew French, a coauthor of the new study and a former graduate student at CU Boulder, now at NASA's Jet Propulsion Laboratory
(JPL).



==========================================================================
What the team has found may also spell trouble for Bennu. The asteroid's
core appears to be weaker than its exterior, a fact that could put its
survival at risk in the not-too-distant future.

"You could imagine maybe in a million years or less the whole thing
flying apart," said Scheeres, a distinguished professor in the Ann and
H.J. Smead Department of Aerospace Engineering Sciences.

Evolution of asteroids Of course, that's part of the fun of studying
asteroids. Scheeres explained that Bennu belongs to a class of smaller
bodies that scientists call "rubble pile" asteroids -- which, as their
name suggests, resemble loosely held- together mounds of debris.

Asteroids also change over time more than people think.



========================================================================== "None of them have sat out there unchanging since the dawn of the solar system," Scheeres said. "They're being changed by things like sunlight affecting how they spin and collisions with other asteroids." To study
how Bennu and other similar asteroids may change, however, he and his colleagues needed to take a peek inside.

This is where the team got lucky. When OSIRIS-REx first arrived at
Bennu, the spacecraft spotted something unusual: Over and over again,
tiny bits of material, some just the size of marbles, seemed to pop off
the asteroid and into space. In many cases, those particles circled Bennu before falling back down to the surface. Members of the mission's radio
science team at JPL were able to witness how the body's gravity worked first-hand -- a bit like the apocryphal story of Isaac Newton inferring
the existence of gravity after observing an apple falling on his head.

"It was a little like someone was on the surface of the asteroid and
throwing these marbles up so they could be tracked," Scheeres said. "Our colleagues could infer the gravity field in the trajectories those
particles took." Squishy center In the new study, Scheeres and his
colleagues combined those records of Bennu's gravity at work with data
from OSIRIS-REx itself -- precise measurements of how the asteroid
tugged on the spacecraft over a period of months. They discovered
something surprising: Before the mission began, many scientists had
assumed that Bennu would have a homogenous interior. As Scheeres put it,
"a pile of rocks is a pile of rocks." But the gravity field measurements suggested something different. To explain those patterns, certain chunks
of Bennu's interior would likely need to be more tightly packed together
than others. And some of the least dense spots in the asteroid seemed
to lie around the distinct bulge at its equator and at its very core.

"It's as if there is a void at its center, within which you could fit
a couple of football fields," Scheeres said.

The asteroid's spin may be responsible for that void. Scientists know
that the asteroid is spinning faster and faster over time. That building momentum could, Scheeres said, be slowly pushing material away from
the asteroid's center and toward its surface. Bennu, in other words,
may be in the process of spinning itself into pieces.

"If its core has a low density, it's going to be easier to pull the
entire asteroid apart," Scheeres said.

For the scientist, the new findings are bittersweet: After measuring
Bennu's gravity field, Scheeres and his team have mostly wrapped up
their work on the OSIRIS-REx mission.

Their results have contributed to the mission's sample analysis plan,
which is currently in development. The returned sample will be analyzed
to determine the cohesion between grains -- a key physical property that affects the mass distribution observed in the team's study.

"We were hoping to find out what happened to this asteroid over time,
which can give us better insight into how all of these small asteroids
are changing over millions, hundreds of millions or even billions of
years," Scheeres said. "Our findings exceeded our expectations."

========================================================================== Story Source: Materials provided by
University_of_Colorado_at_Boulder. Original written by Daniel
Strain. Note: Content may be edited for style and length.


========================================================================== Journal Reference:
1. D. J. Scheeres, A. S. French, P. Tricarico, S. R. Chesley,
Y. Takahashi,
D. Farnocchia, J. W. McMahon, D. N. Brack, A. B. Davis,
R.-L. Ballouz, E.

R. Jawin, B. Rozitis, J. P. Emery, A. J. Ryan, R. S. Park,
B. P. Rush, N.

Mastrodemos, B. M. Kennedy, J. Bellerose, D. P. Lubey, D. Velez,
A. T.

Vaughan, J. M. Leonard, J. Geeraert, B. Page, P. Antreasian,
E. Mazarico, K. Getzandanner, D. Rowlands, M. C. Moreau, J. Small,
D. E. Highsmith, S.

Goossens, E. E. Palmer, J. R. Weirich, R. W. Gaskell,
O. S. Barnouin, M.

G. Daly, J. A. Seabrook, M. M. Al Asad, L. C. Philpott,
C. L. Johnson, C.

M. Hartzell, V. E. Hamilton, P. Michel, K. J. Walsh, M. C. Nolan,
D. S.

Lauretta. Heterogeneous mass distribution of the rubble-pile
asteroid (101955) Bennu. Science Advances, 2020; 6 (41): eabc3350
DOI: 10.1126/ sciadv.abc3350 ==========================================================================

Link to news story: https://www.sciencedaily.com/releases/2020/10/201008170641.htm

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