A tiny fragment from the most dangerous asteroid in the solar system has arrived in the U.K. — and scientists think it could teach us about the origins of life on Earth.
The fragment — a millimeter-size (0.04 inch) slice from the roughly 6-ounce (170 grams) sample that was collected from the asteroid Bennu and may contain the precursors to life — arrived at the Natural History Museum in London Tuesday (Nov. 28).
NASA scientists first revealed the sample on Oct. 11 after it hurtled back to Earth aboard the OSIRIS-REx capsule at speeds of up to 27,000 mph (43,000 km/h). After a seven-year, 4 billion-mile (6.4 billion kilometers) round trip, the capsule deployed its parachute and safely landed in the Utah desert before being transported to Johnson Space Center in Houston. Now, bits of it are being sent around the world for analysis.
"It's almost unbelievably exciting," Sara Russell, a professor of cosmic mineralogy and planetary science at the Natural History Museum, said in a statement. "It's almost like a dream to have the sample back, because we've been thinking about it for so long."
Bennu is a potentially hazardous asteroid that has a 1-in-2,700 chance of striking Earth in the year 2182 — the highest odds of any known space object. But the scientists are more interested in what's trapped inside the space rock: the possible extraterrestrial precursors of life on Earth.
"This is the biggest carbon-rich asteroid sample ever returned to Earth," NASA Administrator Bill Nelson said at a news conference upon the sample's return. "Carbon and water molecules are exactly the elements we wanted to find. They're crucial elements in the formation of our own planet, and they're going to help us determine the origins of elements that could have led to life."
Earth's water is older than the planet itself and was probably brought here by asteroid and comet impacts. But water likely wasn't the only material asteroids brought to Earth; the building blocks of life likely hitched a ride on a space rock, too. Bennu is a B-type asteroid, which means it contains high amounts of carbon and, potentially, many of the primordial molecules present when life emerged on Earth.
Some of these building blocks — including uracil, one of the nucleobases for RNA — were recently found on the asteroid Ryugu by the Japan Aerospace Exploration Agency's Hayabusa2 spacecraft, which returned to Earth with its rock sample in 2020. OSIRIS-REx mission scientists are hoping to find other potential precursors for Earth's biology inside the Bennu sample.
The sample was collected after nearly two years of searching for a landing site on Bennu's craggy surface. Upon making contact with the asteroid, OSIRIS-REx fired a burst of nitrogen from its Touch-and-Go Sample-Acquisition Mechanism to both stick the landing and prevent the craft from sinking through the asteroid.
The blast sent rocks and dust careening around the craft, and some of that rocky debris landed in a canister aboard OSIRIS-REx. A follow-up blast of OSIRIS-REx's thrusters later lifted it from Bennu, and the spacecraft completed a number of flyovers before leaving the asteroid for Earth in May 2021.
Now that the sample has arrived, scientists around the world will begin analyzing it for clues about how our solar system, and the life on our planet, came to be.
"It's kind of like the leftover building block of our solar system," Ashley King, a meteorite researcher at the Natural History Museum, said in the statement. "When we think about how planet Earth formed, all the ingredients are also locked up within Bennu. So we want to disentangle the story of Bennu and learn about the origin of the solar system and then the history of Earth."
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Ben Turner is a U.K. based staff writer at Live Science. He covers physics and astronomy, among other topics like tech and climate change. He graduated from University College London with a degree in particle physics before training as a journalist. When he's not writing, Ben enjoys reading literature, playing the guitar and embarrassing himself with chess.
I have a question regarding the sample recently collected. I read a previous article when the probe and samples had first arrived and the trouble that the team were having with opening the collection chamber. In the pictures provided, I seen how the work was being performed in a "glove-bag" type of enclosure, (or rather, a more solid type of enclosure with glove ports) and I am well acquainted with these working conditions as I currently use very similar enclosures when working with radioactive equipment, or the potential contamination thereof.Reply
So my question is thus....has not the sample been contaminated or otherwise compromised when exposed to air, or for that matter, upon re-entry into our atmosphere? If there were a way to collect the sample in an air-tight enclosure, and to re-open it here within a vacuum under the same extreme conditions of temperature and pressure, would there be any difference in the make-up of the materials found?
Does heat from re-entry or the presence of moisture or other gaseous particulates within our atmosphere possibly change the chemical characteristics of the sample?