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October 13, 2010 12:45 PM (EDT)

News Release Number: STScI-2010-34

Hubble Finds that a Bizarre X-Shaped Intruder Is Linked to an Unseen Asteroid Collision

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Hubble Finds that a Bizarre X-Shaped Intruder Is Linked to an Unseen  Asteroid CollisionView this image

Hubble Finds that a Bizarre X-Shaped Intruder Is Linked to an Unseen Asteroid Collision

Last January astronomers thought they had witnessed a fresh collision between two asteroids when images from NASA's Hubble Space Telescope revealed a bizarre X-shaped object at the head of a comet-like trail of material.

After using Hubble to track the oddball body for five months, astronomers were surprised to find that they had missed the suspected smashup by a year.

"We thought this event had just occurred," says astronomer David Jewitt of the University of California in Los Angeles and leader of the Hubble observations. "We expected the debris field to expand dramatically, like shrapnel flying from a hand grenade. So we rushed to apply for Hubble time to watch the aftermath. But what happened was quite the opposite. We found that the object is expanding very, very slowly and that it started not a week but nearly a year before our January observations."

By his calculation, the encounter happened in February or March 2009. Still, Jewitt is excited about the Hubble observations because they are the first snapshots of a suspected asteroid collision. Jewitt's results appear in the October 14 issue of the science journal Nature.

The peculiar object, dubbed P/2010 A2, was found cruising around the asteroid belt, a reservoir of millions of rocky bodies between the orbits of Mars and Jupiter. Encounters between asteroids are assumed to be common, and destructive. In fact, Jewitt estimates that modest-sized asteroids smash into each other roughly once a year. When the objects collide, they inject dust into interplanetary space. But until now, astronomers have relied on models to make predictions about the frequency of these collisions and the amount of dust produced.

"These observations are important because we need to know where the dust in the solar system comes from, and how much of it comes from colliding asteroids as opposed to 'outgassing' comets," Jewitt explains. "We can also apply this knowledge to the dusty debris disks around other stars, because these are thought to be produced by collisions between unseen bodies in the disks. Knowing how the dust was produced will yield clues about those invisible bodies."

The Hubble images, taken from January to May 2010 with Wide Field Camera 3, reveal a point-like object about 400 feet (120 meters) wide, with a long, flowing dust tail behind a never-before-seen X pattern. The observations also show that the object retained its X shape even as the debris field slowly expanded. Particle sizes in the tail are estimated to vary from about 1/25th of an inch (a millimeter) to an inch (2.5 centimeters) in diameter. P/2010 A2 was 102 million miles from Earth when Hubble first observed it in January 2010.

The 400-foot-wide object in the Hubble image is the remnant of a slightly larger precursor body. Astronomers think a smaller rock, perhaps 10 to 15 feet (3 to 5 meters) wide, slammed into the larger one. The pair probably collided at high speed, about 11,000 miles (18,000 kilometers) an hour, which smashed and vaporized the small asteroid and stripped material from the larger one. Jewitt estimates that the violent encounter was as powerful as the detonation of a small atomic bomb.

Radiation pressure from the Sun then swept the debris behind the remnant asteroid, forming a comet-like tail. The tail contains enough dust to make a ball 65 feet (20 meters) wide, most of it blown out of the bigger body by the impact-caused explosion.

The two asteroids were probably no strangers to collisions. They were themselves most likely relics from impacts between larger asteroids that occurred tens or hundreds of millions of years ago. This collisional grinding from large sizes down to small is thought to be one of the main processes by which asteroids are destroyed.

Astronomers do not have a good explanation for the X shape. The crisscrossed filaments at the head of the tail might suggest that the colliding asteroids were not perfectly symmetrical. Material ejected from the impact, therefore, did not make a symmetrical pattern, a bit like the ragged splash made by throwing a brick into a lake. Larger particles in the X disperse very slowly and give this structure its longevity.

Although the Hubble images give compelling evidence for an asteroid collision, Jewitt says he still does not have enough information to rule out all alternative ideas. In one such scenario, a small asteroid's rotation increases from sunlight pressure and loses mass, forming the comet-like tail.

Catching colliding asteroids is difficult, Jewitt says, because large impacts are rare while small ones, such as the one that produced P/2010 A2, are exceedingly faint. The two asteroids whose remains make up P/2010 A2 were unknown before the smashup because they were too faint to be noticed. The collision itself was unobservable because it happened when the asteroids were in the same direction as the Sun. About 10 or 11 months later, in January 2010, the Lincoln Near-Earth Research (LINEAR) Program Sky Survey spotted the comet-like tail produced by the collision. But only Hubble resolved the X pattern, offering unequivocal evidence that something stranger than a comet outgassing had occurred.

Jewitt is confident that future telescopes will find plenty of asteroid encounters. The planned Large Synoptic Survey Telescope (LSST) should spot dozens of asteroid collisions shortly after they happen, Jewitt says. The LSST is a wide-field survey observatory that will scan the sky weekly for transitory events such as supernovas and near-Earth asteroids.

Astronomers plan to use Hubble again in 2011 to view the remnant asteroid. Jewitt and his colleagues hope to see how far the dust has been swept back by the Sun's radiation and how the mysterious X-shaped structure has evolved.


Donna Weaver
Space Telescope Science Institute, Baltimore, Md.

David Jewitt
University of California, Los Angeles, Calif.