NASA's OSIRIS-REx mission almost bit the dust — then Queen guitarist Brian May stepped in

An artist's depiction of the OSIRIS-REx spacecraft collecting a sample from asteroid Bennu.
An artist's illustration of the OSIRIS-REx spacecraft poised to land on the asteroid Bennu. (Image credit: NASA/Goddard/University of Arizona)

On Sept. 24, NASA's OSIRIS-REx spacecraft will come hurtling back through Earth's atmosphere after a years-long journey to Bennu, a "potentially hazardous asteroid" with a 1 in 2700 chance of smashing cataclysmically into Earth, the highest odds of any identified space object. 

The goal of the mission? To see whether life on Earth came from outer space. But for a nail-biting 22 months, scientists wondered whether they'd be able to land the spacecraft on the asteroid at all.

That the OSIRIS-REx mission ultimately succeeded is in part due to Queen guitarist Brian May, who meticulously created 3D images of the rubble pile to help the mission leaders identify safe landing spots. Thanks to that safe landing, OSIRIS-REx is now returning from its mission with a 2-ounce sample (60 grams) of Bennu's surface that could contain extraterrestrial precursors to life on our planet.

Related: Key building block for life discovered on distant asteroid Ryugu — and it could explain how life on Earth began

"You think asteroids are pieces of junk out there that might hit us and we're very scared of them — whatever. You don't realize that actually, they're probably responsible for us being here," May, who also has a PhD in astrophysics told Live Science. "There would probably be no biosphere without asteroids. And possibly the actual seeds of life came from them as well — it's an incredible thought. So asteroids become absolutely the center of everything: If we understand asteroids, we'll understand ourselves."

A composite image of the asteroid Bennu taken by OSIRIS-REx's on-board cameras. (Image credit: NASA/Goddard/University of Arizona)

Bennu: Bringer of death, God of creation

Viewed from a distance, Bennu looks like an inert, debris-flecked spinning top suspended in space. Categorized as a rubble-pile asteroid, Bennu is an 85.5 million-ton (77.5 million metric tons) collection of rock chunks and boulders barely held together by weak gravity — a cosmic ball pit that swallows any object that lands too hard on its surface, and sends anything that springs too forcefully from it careering into space.

Yet draw closer, as OSIRIS-REx did on its first approach in 2018, and an altogether stranger picture emerges. Veins of carbonate rock 3 feet (0.9 meters) long criss-cross a surface spattered with carbon-rich organic material — evidence that Bennu's parent body, a 60-mile (96 kilometers) wide object which formed during the earliest years of the solar system and split roughly one billion years ago to form the asteroid, was once home to torrents of hot water and the earliest building blocks of life.

Bennu is named after an ancient Egyptian god of creation, and the flight of OSIRIS-REx (short for the Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer) to the asteroid was no less mythic an odyssey. It blasted off from Florida in 2016 and slingshotted around Earth before reaching Bennu's orbit in December 2018.

Sticking the landing

However, OSIRIS-REx didn't just need to get to Bennu: the real trick was landing. Initial thermal surveys of Bennu appeared to suggest it was composed of fine-grained material, much like a beach, according to the mission leader Dante Lauretta, a professor of planetary science and cosmochemistry at the University of Arizona.

But when OSIRIS-REx finally arrived, it encountered a craggy asteroid strewn with sharp boulders that rendered the original landing strategy, which depended on a height-measuring laser altimeter, completely useless. Instead, the team nudged the spacecraft into a tight orbit using Bennu's feeble gravity — making thousands of passes over the rock's surface to search for a safe landing spot.

"Yeah, we were challenged to find a safe location on the asteroid to send our billion dollar spacecraft down to collect a sample," Lauretta told Live Science. "I mean, this is not an easy decision, and it was my decision, right? I was on the hook for this."

An image of OSIRIS-REx's landing site, named Nightingale, on the asteroid Bennu (Image credit: NASA/Goddard/University of Arizona)

To find a suitable parking spot on Bennu, the OSIRIS-REx scientists used their spacecraft's on-board cameras to meticulously map its surface features down to the centimeter. Then, by taking pairs of images side by side from each other, Brian May and his collaborator Claudia Manzoni clipped them together to create stereoscopic images (made by stitching two photos together to recreate the depth perception of two eyes) — enabling the team to fully assess the safety of potential landing sites.

"We're looking at flat images and thinking: 'Well, that might be okay, that looks reasonably safe and flat,' and then all of a sudden it pops out in 3D we're like: 'Err, no,'" Lauretta said.

"Brian was processing scene after scene and I was worried we were never going to find a sampling location," Lauretta added. "Until finally, we saw these small craters shaped like bowls, maybe 10 or 20 meters across, filled with this fine grain material. Then I knew we were onto something."

After 22 months of fraught deliberation, the researchers settled on a site they named Nightingale, which OSIRIS-REx touched down upon on Oct. 20, 2020. To stick the landing and avoid completely sinking through the rubble-pile asteroid's surface, the spacecraft fired a quick blast of nitrogen gas from its Touch-and-Go Sample-Acquisition Mechanism (TAGSAM).

Besides offering the spacecraft a precarious foothold on Bennu's surface, TAGSAM sent dust and broken rock flying in all directions, most importantly into OSIRIS-REx's sample chamber, which collected so much more of the material than expected that it briefly had trouble closing.

Bennu's rubble-pile surface flying in all directions as OSIRIS-REx touches down. Some of the asteroid's surface, or regolith, was captured inside the spacecraft's sample retrieval container. (Image credit: NASA/Goddard/University of Arizona)

What's in the box?

What exactly is hiding among the rocks collected in OSIRIS-REx's sample is anyone's guess, the mission scientists say, but the possibilities are thrilling.

"We don't know till we get it, but just looking at the images that Dante and Brian have sent back, it looks like it's full of lots of different kinds of rock, some of which are really fragile, which means they would never have got to Earth as meteorites," Sara Russell, a professor of planetary sciences and leader of the Planetary Materials Group that will be analyzing a part of the sample at the Natural History Museum, London, told Live Science. "My hope is that it will tell us something that we didn't even know that we didn't know."

The story of the asteroid Bennu and OSIRIS-REx's journey is told in a new book brimming with Brian May's images. It also features a 3D eye-piece designed by the rock god himself. "Bennu: 3-D Anatomy of an Asteroid", written by May and OSIRIS-REx principal investigator Dante Lauretta, is available in the U.S. from University of Arizona Press and in the U.K. from London Stereoscopic Company.

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Ben Turner
Live Science Staff Writer

Ben Turner is a U.K. based staff writer at Live Science. He covers physics and astronomy, among other topics like weird animals 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.