Universe Today
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This composite of 25 images of asteroid 2017 BQ6 was generated with radar data collected using NASA's Goldstone Solar System Radar in California's Mojave Desert. It sped by Earth on Feb. 7 at a speed of around 25,560 mph (7.1 km/s) relative to the planet. The images have resolutions as fine as 12 feet (3.75 meters) per pixel. Credit: NASA/JPL-Caltech/GSSR[/caption]
To radar imager
Lance Benner
at JPL in Pasadena, asteroid 2017 BQ6 resembles the
polygonal dice
used in
Dungeons and Dragons
. But my eyes see something closer to a stepping stone or paver you'd use to build a walkway. However you picture it, this asteroid is more angular than most imaged by radar.
It flew harmlessly by Earth on Feb. 7 at 1:36 a.m. EST (6:36 UT) at about 6.6 times the distance between Earth and the moon or some about 1.6 million miles. Based on 2017 BQ6's brightness, astronomers estimate the hurtling boulder about 660 feet (200 meters) across. The recent flyby made for a perfect opportunity to bounce radio waves off the object, harvest their echoes and build an image of giant space boulder no one had ever seen close up before.
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NASA's 70-meter antennas are the largest and most sensitive Deep Sky Network antennas, capable of tracking a spacecraft traveling tens of billions of miles from Earth. This one at Goldstone not only tracked Voyager 2's Neptune encounter, it also received Neil Armstrong's famous communication from Apollo 11: "That's one small step for a man. One giant leap for mankind." Credit: JPL-Caltech/GSSR[/caption]
The images of the asteroid were obtained on Feb. 6 and 7 with NASA's 230-foot (70-meter) antenna at the
Goldstone Deep Space Communications Complex
in California and reveal an irregular, angular-appearing asteroid:
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Animation of 2017 BQ6. The near-Earth asteroid has a rotation period of about 3 hours. Credit: NASA/JPL-Caltech/GSSR[/caption]
"The radar images show relatively sharp corners, flat regions, concavities, and small bright spots that may be boulders," said Lance Benner of NASA's Jet Propulsion Laboratory in Pasadena, California, who leads the agency's asteroid radar research program. "Asteroid 2017 BQ6 reminds me of the dice used when playing Dungeons and Dragons."
2017 BQ6 was
discovered
on Jan. 26 by the NASA-funded
Lincoln Near Earth Asteroid Research (LINEAR) Project
, operated by MIT Lincoln Laboratory on the Air Force Space Command's Space Surveillance Telescope at White Sands Missile Range, New Mexico.
Radar has been used to observe hundreds of asteroids. Even through very large telescopes, 2017 BQ6 would have appeared exactly like a star, but the radar technique reveals shape, size, rotation, roughness and even surface features.
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This chart shows how data from NASA's Wide-field Infrared Survey Explorer, or WISE, has led to revisions in the estimated population of near-Earth asteroids. Credit: NASA/JPL-Caltech[/caption]
To create the images, Benner conducted a controlled experiment on the asteroid, transmitting a signal with well-known characteristics to the object and then, by comparing the echo to the transmission, deduced its properties. According to NASA's
, measuring how the echo power spreads out over time along with changes in its frequency caused by the Doppler Effect (object approaching or receding from Earth), provide the data to construct two-dimensional images with resolutions finer than 33 feet (10 meters) if the echoes are strong enough.
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This orbital diagram shows the close approach of 2017 BQ6 to Earth on Feb. 7, 2017. Credit: NASA/JPL Horizons[/caption]
In late October 2016, the number of known near-Earth asteroids topped 15,000 with new discoveries averaging about 30 a week. A near-Earth asteroid is defined as a rocky body that approaches within approximately 1.3 times Earth's average distance to the Sun. This distance then brings the asteroid within roughly 30 million miles (50 million km) of Earth's orbit. To date, astronomers have already discovered more than 90% of the estimated number of the
large
near-Earth objects or those larger than 0.6 miles (1 km). It's estimated that more than a million NEAs smaller than 330 feet (100 meters) lurk in the void. Time to get crackin'.