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Waspie_Dwarf

Nov 18 2006, 01:39 AM

Observations of double asteroid stress Arecibo radar's vital role in identifying threats in Earth's vicinity

The Cornell University press release is reproduced below:

Nov. 15, 2006

Observations of double asteroid stress Arecibo radar's vital role in identifying threats in Earth's vicinity

By Lauren Gold

Researchers using the Arecibo Observatory's powerful radar have made the most detailed observations ever of a binary near-Earth asteroid (NEA) -- two clusters of rubble circling each other -- offering new clues about how such systems formed, the properties they share and the dynamics of their motion.
asteroid KW4

IPB Image

The new data allow the most detailed shape models ever of a
potentially hazardous asteroid. Alpha, KW4's larger component,
is spinning so fast that particles on its surface feel themselves
being pulled toward the equatorial ridge; that is, they fall toward
the highest part of the surface.

The observations, made by Steve Ostro, senior research scientist at the NASA/Caltech Jet Propulsion Laboratory in Pasadena (who earned his master's degree in engineering physics at Cornell), Jean-Luc Margot, assistant professor of astronomy at Cornell, and their colleagues, describe asteroid (66391) 1999 KW4 (called KW4). Their report appears in the latest issue (Nov. 24) of the journal Science. The double asteroid also appears on the cover.

KW4, they say, is actually a pair of light, porous clusters of rubble that circle each other as they orbit from a point closer to the sun than Mercury and then outward -- occasionally passing very close to Earth along the way. The bodies were discovered in 1999 but were not known to be binary until they were observed in May 2001, when they came within about 2.98 million miles of Earth -- their closest pass until 2036.

The researchers used antennas at Arecibo and NASA's Goldstone Deep Space Network -- the only telescopes with the radar capability for such observations. Arecibo, in Puerto Rico, is managed by the National Astronomy and Ionosphere Center at Cornell for the National Science Foundation.

KW4 is a valuable source of information for planetary scientists studying the formation and evolution of NEAs -- as well as for researchers studying how to mitigate the potential threat they pose to Earth. KW4 is classified a Potentially Hazardous Asteroid, but data show that its path will not intersect Earth's for at least 1,000 years.

Unlike single asteroids, many of whose physical properties are impossible to determine from Earth-based observations, binaries can reveal information about their mass and density by their interaction with each other. The researchers were able to reconstruct the orbit, mass, shape and density of KW4's two components, Alpha and Beta. They found an oddly shaped pair of dance partners, with Alpha, by far the larger (1.5 kilometers, or a little less than one mile, in diameter) of the two, spinning as fast as possible without breaking apart, and the smaller and denser Beta wobbling noticeably as it orbits its partner.

"It's the first time we have very detailed high-resolution images that allowed us to derive the shape of both components," said Margot. Viewed pole-on, Alpha looks circular; but from the side it looks more like a squashed diamond with rounded edges, showing a distinct ridge at the equator. A particle on Alpha's surface will be pulled toward the equator -- which means, strangely, that the body's highest point is also its lowest.

The study also involved the most precise tracking of an irregularly shaped binary system's motion -- information vital in learning how the two asteroids formed.

"The overwhelming majority of these binaries have primary components whose spins are very near the maximum of what they can sustain. It's a distinctive feature," said Margot. That indicates the systems could have been a single asteroid -- or pieces of a larger asteroid -- that were sent spinning by a close encounter with another body or by the effects of sunlight.

The system's orbit has brought it within about 9.3 million miles of Earth or closer dozens of times in the last several millennia, but not near any other planet.

As a whole, the Arecibo/Goldstone data on KW4 take the understanding of NEAs to a new level of precision, say researchers. The study also highlights the value of both telescopes involved: NASA's Goldstone, which is more steerable, and Arecibo, whose radar is an order of magnitude more powerful.

"They are complementary and both are essential," said Margot. Goldstone can track objects over a longer time period, but "you couldn't do it at this level of precision without the Arecibo data."

Source: Cornell University - Chronicle Online

Waspie_Dwarf

Mar 30 2007, 12:08 AM

The Impossible Siblings

The European Southern Observatory (ESO) press release 18-07 is reproduced below:

ESO 18/07 - Science Release

29 March 2007
For Immediate Release

The Impossible Siblings

Unique Data Collected on Double Asteroid Antiope

Combining precise observations obtained by ESO's Very Large Telescope with those gathered by a network of smaller telescopes, astronomers have described in unprecedented detail the double asteroid Antiope, which is shown to be a pair of rubble-pile chunks of material, of about the same size, whirling around one another in a perpetual pas de deux. The two components are egg-shaped despite their very small sizes.

The asteroid (90) Antiope was discovered in 1866 by Robert Luther from Dusseldorf, Germany. The 90th asteroid ever discovered, its name comes from Greek mythology. In 2000, William Merline and his collaborators found that the asteroid was composed of two similarly-sized components, making it a truly 'double' asteroid, one of the very first of this kind in the main belt of asteroids that lies between the orbits of Mars and Jupiter.

Artist's impression of the double asteroid Antiope. Both components are shown to have a quasi-spherical shape.

"The way double asteroids have formed in the main belt is still unclear," says Pascal Descamps, from the Paris Observatory and lead-author of the paper presenting the new results. "The Antiope system provides us with a unique opportunity to know more about this class of objects and we decided to study it in detail," he adds.

Descamps, with colleague Franck Marchis from the University of California at Berkeley, USA, therefore initiated a large campaign of observations for more than two and a half years starting in January 2003. They used the NACO instrument on ESO's Very Large Telescope at Cerro Paranal for the larger part, while using one of the Keck telescopes for some additional observations in 2005.

NACO allows the astronomers to perform adaptive optics observations, providing images that are mostly free from the blurring effect of the atmosphere. With these, it was always possible to separate clearly the two components of the Antiope system, thereby obtaining a large set of very precise measurements of their positions.

"With this unique set of data, we could determine with utmost precision the course of the two pieces of cosmic rock as they turn around each other," says Marchis. "We found that the two objects are separated by 171 km, and that they perform their celestial dance in 16.5 hours. In fact, we now know this orbital period with a precision of better than half a second."

With the orbit determined, the astronomers could derive the total mass of the system: 828 millions million tons, and found the two objects were rotating around their own axes at the same speed as they orbit each other. Thus, in the same way than the Moon does to the Earth, they always present to each other the same side (something astronomers call 'tidal locking'). Moreover, the two asteroids rotate in the same plane as they orbit each other.

VLT observations of the double asteroid (90) Antiope during 2004. The adaptive optics NACO instrument was used, allowing the astronomers to perfectly distinguish the two components and so, precisely determine the orbit. The two objects are separated by 171 km, and they perform their celestial dance in 16.5 hours. The adaptive optics observations could, however, never resolve the shape of the individual components as they are too small.

The adaptive optics observations could, however, never resolve the shape of the individual components as they are too small. "But with the new orbit, we could precisely predict that from the end of May to the end of November 2005 the system would present eclipses and occultations," says Marchis. "Such 'mutual events' are unique opportunities to learn a great deal about this double asteroid."

The astronomers invited observers around the world to turn their eyes on the asteroid pair to measure the drops in brightness resulting from the predicted events. Over the six-month period, amateurs and professionals from as far afield as Brazil, Chile, France, Réunion Island, South Africa, and the USA, observed repeated occultations as well as shadows passing over one of the pair.

With this new data, Descamps, Marchis and their team, found enough evidence that the two mountain-like chunks of material forming the Antiope system have the shape of ellipsoids, that is, slightly deformed spheres, almost similar in size: 93.0 x 87.0 x 83.6 km and 89.4 x 82.8 x 79.6 km, respectively. Each asteroid in the pair is thus roughly the size of a large city.

Perhaps the most astonishing result is the fact that the two components have a shape close to the one predicted by the French scientist Edouard Roche in 1849 for self-gravitating, rotating fluid objects orbiting each other and tidally locked.

Of course, the asteroids are not gaseous nor liquids, they are solids, but their internal structure must be so loose that their bodies can readjust themselves due to the gravitational influence of the companion.

The scientists were also able to derive the density of the objects, only a quarter higher than the density of water. This means the asteroids are very porous, having 30 percent empty space, and thereby suggesting a rubble-pile structure. This structure could explain why it was easier for the asteroids to reach equilibrium shapes, while being so small.

"Despite this intensive study, the origin of this unique doublet still remains a mystery," says Descamps. "The formation of such a large double system is an improbable event and represents a formidable challenge to theory. One possibility is that a parent body was spun up so much that it took the shape of an apple core, then split into two similar-sized pieces."

More Information

This work is reported in a paper published in the journal Icarus ("Figure of the double Asteroid 90 Antiope from adaptive optics and lightcurve observations", by P. Descamps et al.).

The team is composed of P. Descamps, F. Marchis, F. Vachier, F. Colas, J. Berthier, D. Hestroffer, R. Viera-Martins, and M. Birlan (Observatoire de Paris, France), T. Michalowski and M. Polinska (Adam Mickiewicz University, Poznan, Poland), M. Assafin (Observatorio do Valongo/UFRJ, Brazil), P.B. Dunckel (Rattlesnake Creek Observatory, USA), W. Pych (Nicolaus Copernicus Astronomical Center, Warsaw, Poland), J.-P. Teng-Chuen-Yu, A. Peyrot, B. Payet, J. Dorseuil, Y. Léonie, and T. Dijoux (Makes Observatory, Réunion Island, France). F. Marchis is also at the University of California at Berkeley, USA.

Source: ESO Press Release pr-18-07

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