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Waspie_Dwarf

Mar 8 2007, 07:08 AM

Solar Power at Play

The European Southern Observatory (ESO) press release 11-07 is reproduced below:

ESO 11/07 - Science Release

7 March 2007
For Immediate Release

Solar Power at Play

Observing the Spin-Up of an Asteroid

For the very first time, astronomers have witnessed the speeding up of an asteroid's rotation, and have shown that it is due to a theoretical effect predicted but never seen before. The international team of scientists used an armada of telescopes to discover that the asteroid's rotation period currently decreases by 1 millisecond every year, as a consequence of the heating of the asteroid's surface by the Sun. Eventually it may spin faster than any known asteroid in the solar system and even break apart.

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Asteroid 2000 PH5 imaged with ESO's 3.5m New Technology Telescope in Chile on August 27, 2003, over a time span of 77 minutes. The
asteroid can be seen moving relative to the background stars.

"The Yarkovsky-O'Keefe-Radzievskii-Paddack (YORP) effect is believed to alter the way small bodies in the Solar System rotate," said Stephen Lowry (Queens University Belfast, UK), lead-author of one of the two companion papers in which this work is reported [1, 2].

"The warming caused by sunlight hitting the surfaces of asteroids and meteoroids leads to a gentle recoil effect as the heat is released," he added. "By analogy, if one were to shine light on a propeller over a long enough period, it would start spinning."

Although this is an almost immeasurably weak force, its effect over millions of years is far from negligible. Astronomers believe the YORP effect may be responsible for spinning some asteroids up so fast that they break apart, perhaps leading to the formation of double asteroids. Others may be slowed down so that they take many days to complete a full turn. The YORP effect also plays an important role in changing the orbits of asteroids between Mars and Jupiter, including their delivery to planet-crossing orbits, such as those of near-Earth asteroids. Despite its importance, the effect has never been seen acting on a solar system body, until now.

Using extensive optical and radar imaging from powerful Earth-based observatories, astronomers have directly observed the YORP effect in action on a small near-Earth asteroid, known as (54509) 2000 PH5.

Shortly after its discovery in 2000, it was realised that asteroid 2000 PH5 would be the ideal candidate for such a YORP detection. With a diameter of just 114 metres, it is relatively small and so more susceptible to the effect. Also, it rotates very fast, with one 'day' on the asteroid lasting just over 12 Earth minutes, implying that the YORP effect may have been acting on it for some time. With this in mind, the team of astronomers undertook a long term monitoring campaign of the asteroid with the aim of detecting any tiny changes in its rotation speed.

Over a 4-year time span, Stephen Lowry, Alan Fitzsimmons and colleagues took images of the asteroid at a range of telescope sites including ESO's 8.2-m Very Large Telescope array and 3.5-m New Technology Telescope in Chile, the 3.5-m telescope at Calar Alto, Spain, along with a suite of other telescopes from the Czech Republic, the Canary Islands, Hawaii, Spain and Chile. With these facilities the astronomers measured the slight brightness variations as the asteroid rotated.

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Radar images obtained at the Arecibo facility in Puerto Rico on July 28,
2004, covering one full rotation of asteroid 2000 PH5 (columns 1 and 4).
Corresponding shape-model fits to the images are shown in columns 2
and 5. Columns 3 and 6 are detailed 3-D renderings of the shape model
itself.

Over the same time period, the radar team led by Patrick Taylor and Jean-Luc Margot of Cornell University employed the unique capabilities of the Arecibo Observatory in Puerto Rico and the Goldstone radar facility in California to observe the asteroid by 'bouncing' a radar pulse off the asteroid and analysing its echo.

"With this technique we can reconstruct a 3-D model of the asteroid's shape, with the necessary detail to allow a comparison between the observations and theory," said Taylor.

After careful analysis of the optical data, the asteroid's spin rate was seen to steadily increase with time, at a rate that can be explained by the YORP theory. Critically, the effect was observed year after year, for more than 4 years. Furthermore, this number was elegantly supported via analysis of the combined radar and optical data, as it was required that the asteroid is increasing its spin rate at exactly this rate in order for a satisfactory 3-D shape model to be determined.

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Relative change in the rotation period as a function of time. The observed relative variation in the rotation period is seen to change from
year to year (black dots). The solid curve is the expected theoretical YORP strength derived from the 3-D shape model.

Watch the Asteroid Move!

This movie shows the asteroid moving against the background stars and galaxies over a period of 2 hours in September 2004, as seen with the ESO 8.2-m VLT array in Chile. Rapid brightness modulations can be seen as the asteroid rotates: The movie clearly illustrates how the object is streaking across the sky, but if you look closely you can actually see the asteroid's brightness modulating periodically. It's unusual to see this directly on such a movie but the stable conditions at the VLT and the power of the telescope allowed this modulation to show up quite well (Credit: A. Fitzsimmons).

To predict what will happen to the asteroid in the future, Lowry and his colleagues performed detailed computer simulations using the measured strength of the YORP effect and the detailed shape model. They found that the orbit of the asteroid about the Sun could remain stable for up to the next 35 million years, allowing the rotation period to be reduced by a factor of 36, to just 20 seconds, faster than any asteroid whose rotation has been measured until now.

"This exceptionally fast spin-rate could force the asteroid to reshape itself or even split apart, leading to the birth of a new double system," said Lowry.

Notes

[1] Stephen C. Lowry, Alan Fitzsimmons, Petr Pravec, David Vokrouhlicky, Hermann Boehnhardt, Patrick A. Taylor, Jean-Luc Margot, Adrian Galad, Mike Irwin, Jonathan Irwin, and Peter Kusnirak (2007). Direct Detection of the Asteroidal YORP Effect, Published online in Science Express.

[2] Patrick A. Taylor, Jean-Luc Margot, David Vokrouhlicky, Daniel J. Scheeres, Petr Pravec, Stephen C. Lowry, Alan Fitzsimmons, Michael C. Nolan, Steven J. Ostro, Lance A. M. Benner, Jon D. Giorgini, Christopher Magri (2007). Spin Rate of Asteroid (54509) 2000 PH5 Increasing due to the YORP Effect, Published online in Science Express.

Source: ESO Press Release pr-11-07

Waspie_Dwarf

Mar 8 2007, 07:29 AM

Asteroids spin at YORP speed, thanks to the effects of sunlight, Cornell and Belfast astronomers discover

The Cornell University press release is reproduced below:

March 7, 2007

By Lauren Gold

Sunlight alone can change the way an asteroid and other small bodies spin in space, suggests a new study led by astronomers at Cornell and Queen's University Belfast. Their observations provide the most conclusive evidence to date that an effect of sunlight called YORP plays a direct role in the evolution of asteroids.

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Lindsay France/University Photography
If light shines on a propeller, it will start to spin. Assistant professor of astronomy
Jean-Luc Margot, left, and Cornell graduate student Patrick Taylor have shown that
sunlight can significantly change the spin of asteroids.

Cornell graduate student Patrick Taylor and assistant professor of astronomy Jean-Luc Margot mapped the shape and located the spin pole of a 100-meter-diameter (about 300 feet) near-Earth asteroid called (54509) 2000 PH5 (abbreviated to PH5) between 2001 and 2005, using radar at the National Science Foundation's (NSF) Arecibo Observatory in Puerto Rico and NASA's Goldstone telescope in California.

Meanwhile, a team led by astronomers Stephen Lowry and Alan Fitzsimmons in Belfast used telescopes around the world to measure PH5's light curve, the varying brightness of the asteroid as it rotates. They found that PH5's spin, already unusually fast at about 12 minutes per rotation, is accelerating by about one millisecond per year.

The researchers, reporting on Science magazine's online service, Science Express, on March 8, say that by ruling out other potential forces on PH5, such as tidal torques, they were able to demonstrate that the most likely culprit for the acceleration is the YORP effect from sunlight.

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Rendering of the shape model of 2000 PH5
spinning on its axis. The actual rotation
period is 12.17 minutes and is decreasing
due to the YORP effect.

The acronym, from the tongue-twisting Yarkovsky-O'Keefe-Radzievskii-Paddack, is an effect that occurs when photons from the sun are absorbed by a body and reradiated as heat. In the process, two forces influence the object: one from the impact of the photons, providing a tiny push, and the other as a recoil effect when the object emits the absorbed energy. For small, irregularly shaped objects like PH5, YORP can cause measurable changes in motion.

On average, asteroids rotate every four to 12 hours. But the smallest asteroids (with a diameter of less than 10 kilometers, or about 6 miles) tend to spin either unusually slowly or unusually quickly -- and astronomers have long wondered why.

"It is one of the significant and longstanding questions in asteroid science," said Margot. "YORP is more effective on small objects, so it can nicely explain this."

YORP could also explain why some asteroids come in pairs. Most asteroids are actually loosely bound clumps of rubble with very little internal cohesion, so an object with an increasing spin rate could eventually spin faster than its own strength and gravity can endure -- ultimately flying apart to form two objects. Several dozen asteroids are known to be binaries, with potentially many more undiscovered.

PH5 was discovered in 2000 by the Massachusetts Institute of Technology's near-Earth asteroid search program. When it was observed, it was about five times more distant than the moon.

Before the researchers could attribute the asteroid's accelerating spin to YORP, they had to discount the other possible torques that could be influencing its rotation. Using a shape model produced from high-resolution images gathered by the Arecibo telescope, the team led by Lowry and Fitzsimmons found that tidal torques as the asteroid passed near Earth were not strong enough to account for the acceleration. In fact, tidal forces are just as likely to decelerate the spin.

Beyond the finding's significance to asteroid science, it is also a testament, said Margot, to the unique capabilities of the Arecibo telescope, which is managed for the NSF by the National Astronomy and Ionosphere Center at Cornell.

"Arecibo is absolutely critical for this experiment," said Margot. And while one millisecond may sound trivial, he added, even a change that small adds up. "The length of the day on PH5 can be halved in half a million years," he said. "Anything, even a minute change in our lifetime, can have a dramatic effect in geological timescales."

Source: Cornell University - Chronicle Online

Owlscrying

Mar 8 2007, 11:12 AM

i find logic most applicable as to when sunlight hits the asteroid, the solar energy is absorbed and then radiated back into space. When the asteroid is not spherical, this can create a push off parts of its surface that alters its spin.
very cool !

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