Perseverance rover: NASA’s Mars car to seek signs of ancient life

NASA’s Perseverance rover isn’t just exploring the Red Planet. The life-hunting robot will also help a little bit of Mars make it to Earth a decade or so from now, if all goes according to plan.

Perseverance, the centerpiece of NASA’s $2.7 billion Mars 2020 mission, touched down inside the Red Planet’s Jezero Crater on Feb. 18, 2021. Once it’s fully up and running, the car-sized robot will search for evidence of past microbial life and collect  several dozen samples for future return to Earth, among other ambitious tasks.

“I don’t think we’ve had a mission that is going to contribute so much to both science and technology,” NASA Acting Administrator Steve Jurczyk told Space.com shortly before Perseverance touched down. “It’s going to be truly amazing.”

Live updates: NASA’s Perseverance rover on Mars
More:
Where to find the latest Mars photos from Perseverance

Perseverance rover size: How big is the Mars rover?

If Perseverance looks familiar, that’s because the robotic explorer is largely based off its predecessor, the Mars Science Laboratory (MSL) Curiosity rover, which landed in August 2012 and is still going strong today. 

Like Curiosity, the Perseverance rover was built by engineers and scientists at NASA’s Jet Propulsion Laboratory in Pasadena, California. Roughly 85% of Perseverance’s mass is based on Curiosity “heritage hardware,” saving NASA time and money and reducing risk considerably, agency officials have said.

Perseverance is about 10 feet long (not including its robotic arm), 9 feet wide, and 7 feet tall (about 3 meters long, 2.7 meters wide and 2.2 meters tall). At 2,260 lbs. (1,025 kilograms), Perseverance weighs less than a compact car

Like Curiosity, Perseverance has a rectangular body, six wheels, a robotic arm, a drill for sampling rocks, cameras and scientific instruments. But those instruments are quite different than the gear aboard Curiosity, because the two rovers have divergent goals. Curiosity’s main task involves assessing the habitability of ancient Mars, whereas Perseverance will hunt for evidence of ancient Martians.

Perseverance’s seven instruments “build on the success of MSL, which was a proving ground for new technology,” said George Tahu, NASA’s Perseverance program executive. “These will gather science data in ways that weren’t possible before.”

Image 1 of 12

Illustration of NASA's Perseverance rover on Mars.

(Image credit: NASA/JPL-Caltech)
Image 2 of 12

Mars rover 2020 instruments

(Image credit: NASA/JPL-Caltech)
Image 3 of 12

An artist's depiction of NASA's Mars 2020 rover, Perseverance, storing samples of Martian rocks in tubes for a later rover to fetch and carry to Earth.

(Image credit: NASA/JPL-Caltech)
Image 4 of 12

The ingenuity drone.

(Image credit: NASA/JPL-Caltech)
Image 5 of 12

Mars rover 2020 preparations.

(Image credit: NASA/JPL-Caltech)
Image 6 of 12

Mars rover 2020 parachute

(Image credit: NASA/JPL-Caltech/Ames)
Image 7 of 12

Mars rover 2020 preparations.

(Image credit: NASA/JPL-Caltech)
Image 8 of 12

Mars rover 2020 preparations.

(Image credit: NASA/JPL-Caltech/KSC)
Image 9 of 12

Mars rover 2020 launch.

(Image credit: NASA TV)
Image 10 of 12

Mars rover 2020 launch.

(Image credit: Joel Kowsky/NASA)
Image 11 of 12

Mars rover 2020 launch.

(Image credit: ULA)
Image 12 of 12

Mars rover 2020 launch.

(Image credit: ULA)

Perseverance also used the same entry, descent and landing (EDL) strategy as Curiosity. Both rovers hit the Mars atmosphere at tremendous speeds, deployed a supersonic parachute after friction slowed them down enough, and were finally lowered gently to the red dirt on cables by a rocket-powered “sky crane.”

But Perseverance had some EDL upgrades that Curiosity did not enjoy. For example, NASA’s Jet Propulsion Laboratory in Southern California, which manages the Mars 2020 mission, developed new landing technology called terrain-relative navigation. As the rover descended through the Martian skies, it used a computer to compare the landscape with pre-loaded terrain maps, guiding itself to a safe landing site and making corrections on the way down.

Another new feature, known as range trigger, used location and velocity information to determine when to open the supersonic parachute, narrowing the landing ellipse by more than half.

“Terrain-relative navigation enables us to go to sites that were ruled too risky for Curiosity to explore,” said JPL’s Al Chen, Perseverance’s EDL lead. “The ranger trigger lets us land closer to areas of scientific interest, shaving miles — potentially as much as a year — off a rover’s journey.”

Perseverance rover’s Mars landing: Everything you need to know

Perseverance rover science: Cameras, instruments and more

Perseverance boasts nearly five times more cameras than the first Mars rover. Sojourner, which landed in 1997, carried only five cameras, and the twin rovers Spirit and Opportunity, which hit the red dirt in 2004, had 10 cameras apiece. Curiosity has 17. 

Perseverance has 23 cameras. Several of them filmed the rover’s Mars arrival, capturing its landing in historic and unprecedented detail. The epic EDL video shows Perseverance’s parachute snap open in the Martian sky, for example, and documents the moment the robot’s six wheels hit the red dirt.

“For those who wonder how you land on Mars, or why it is so difficult, or how cool it would be to do so — you need look no further,” Jurczyk said in a statement a few days after touchdown.

“Perseverance is just getting started and already has provided some of the most iconic visuals in space exploration history,” he added. “It reinforces the remarkable level of engineering and precision that is required to build and fly a vehicle to the Red Planet.”

Illustration depicting the science instruments carried aboard NASA’s Mars 2020 Perseverance rover. (Image credit: NASA)

Some of Perseverance’s cameras provide more color and 3D imaging than Curiosity can collect, according to Jim Bell of Arizona State University, the principal investigator for Perseverance’s Mastcam-Z camera system. “Z” stands for “zoom,” one of the improvements on Curiosity’s high-definition Mastcam. 

Spirit, Opportunity and Curiosity have all captured 1-megapixel images in black and white with their engineering cameras, which assist in drive planning and hazard avoidance. But Perseverance’s engineering cameras acquire high-resolution, 20-megapixel color images. Their wider field of view means that, instead of spending time taking multiple images to be stitched together on the ground, the new cameras capture the same view in a single snapshot. The cameras also reduce motion blur, so they can take photos while the rover is traveling.

More detailed images mean more data to beam through space.

“The limiting factor in most imaging systems is the telecommunications link,” said Perseverance imaging scientist Justin Maki of JPL, the instrument operations team chief. “Cameras are capable of acquiring much more data than can be sent back to Earth.”

Related: Perseverance rover snaps gorgeous HD panorama of Mars

The Perseverance rover’s Mastcam-Z is an an advanced camera system with panoramic and stereoscopic imaging capability with a zoom capability. (Image credit: NASA)

Smarter rover cameras are helping to reduce the load. On Spirit and Opportunity, photo compression was done using the onboard computer. On Perseverance, as on Curiosity, compression is performed by electronics built into the camera. 

Perseverance’s data is beamed back to Earth via several spacecraft orbiting Mars: NASA’s Mars Odyssey, Mars Reconnaissance Orbiter (MRO) and MAVEN (Mars Atmosphere and Volatile Evolution), and the European Space Agency’s Trace Gas Orbiter. 

Odyssey was the first orbiter to send rover data home from Spirit and Opportunity. 

“We were expecting to do that mission on just tens of megabits each Mars day, or sol,” Bell said, referring to Spirit and Opportunity’s work. “When we got that first Odyssey overflight, and we had about 100 megabits per sol, we realized it was a whole new ballgame.”

Mastcam-Z is one of Perseverance’s seven science instruments. Another, known as SHERLOC (“Scanning Habitable Environments with Raman and Luminescence for Organics and Chemicals”), will be the first instrument on Mars to use Ramen and fluorescence spectroscopies, techniques familiar to forensics experts. 

When an ultraviolet light shines over certain carbon-based chemicals, they glow much like material beneath a black light. The glow can help scientists detect chemicals that form in the presence of life. SHERLOC will photograph the rocks it studies, then map the chemicals it detects across the images.

“This kind of science requires texture and organic chemicals — two things that our target meteorite will provide,” Rohit Bhartia of JPL, SHERLOC’s deputy principal investigator, said in a statement.

The space rock mentioned by Bhartia is the Martian meteorite Sayh al Uhaymir 008 (SaU008), which the team will use to help calibrate SHERLOC. Previous rovers have included calibration targets, but none of them have ever relied on Martian meteorites. (A meteorite has, however, ridden to Mars aboard the Mars Global Surveyor, which ceased operations in January 2007.)

More: 5 weird things NASA’s Perseverance rover took to Mars

Another Perseverance instrument, called PIXL (“Planetary Instrument for X-ray Lithochemistry”), will determine the composition of Martian materials at a very fine scale using a high-resolution camera and X-ray fluorescence spectrometer. 

The rover’s SuperCam instrument, an evolution of Curiosity’s ChemCam, will zap target rocks with lasers and determine the chemical composition of the resulting vapor.

Perseverance also carries a ground-penetrating radar instrument called RIMFAX (“Radar Imager for Mars’ Subsurface Experiment”). RIMFAX will be the first rover instrument ever to look under the surface of Mars, mapping layers of rock, water and ice up to 33 feet (10 m) deep.

Also aboard the rover is a weather station known as MEDA (“Mars Environmental Data Analyzer”) and a technology demonstration called MOXIE (“Mars Oxygen In-Situ Resource Utilization Experiment”). 

MOXIE is designed to generate oxygen from the Red Planet’s atmosphere, which is 95% carbon dioxide by volume. Such gear, if scaled up, could help humanity get a foothold on the Red Planet in the future, NASA officials have said. (The agency aims to put boots on Mars in the 2030s.)

SHERLOC, PIXL and Perseverance’s rock drill sit at the end of the rover’s 7-foot-long (2.1 m) robotic arm, which can move with five degrees of freedom. MEDA, MOXIE and RIMFAX are on Perseverance’s body, and Mastcam-Z and SuperCam are on the rover’s headlike mast.

Perseverance rover’s Mars microphone

Perseverance also carries two microphones, to relay the sounds of the Red Planet back to Earth. One is part of the EDL camera system, and the other is built into SuperCam.

The mission team hoped the EDL mic would record sound during Perseverance’s touchdown. That didn’t happen, but the instrument did switch on shortly after landing, collecting the first-ever true audio on the surface of Mars. (Two other NASA Mars missions, the Mars Polar Lander and Phoenix lander, carried microphones, but neither of them returned any audio data. Mars Polar Lander crashed in December 1999, and Phoenix’s mic was never turned on, out of concern that it could interfere with the spacecraft’s May 2008 touchdown.)

Listen to the Mars wind blow in these 1st sounds from the Perseverance

Hearing these otherworldly sounds helps bring Mars down to Earth for all of us, making the Red Planet a more accessible place, mission team members have said. And Mars audio has more than just gee-whiz appeal.

“There’s a lot of good science that can be done by having a microphone on Mars,” SuperCam team member Sylvestre Maurice, a planetary scientist at the Research Institute in Astrophysics and Planetology in France, told Space.com

For example, once SuperCam comes online, the mic should help reveal how hard target rocks are and whether or not they have a coating. Martian audio will also improve our understanding of the Red Planet’s thin atmosphere, by providing data to plug into models, mission team members have said.

It’s possible that Perseverance will even gather stereo sound on the Martian surface, by operating the EDL and SuperCam mics in concert. 

The first Mars helicopter: Meet Ingenuity

Perseverance also carried a tiny hitchhiker to Mars — a 4-lb. (1.8 kg) helicopter named Ingenuity, which will attempt to make the first-ever rotorcraft flights on a world beyond Earth.

Like MOXIE, Ingenuity is a technology demonstration; it carries a high-resolution camera but no science instruments. If the little chopper does manage to get off the Martian ground, helicopters could become a staple of Red Planet exploration in the future, gathering a variety of data on their own and/or serving as scouts for rovers, NASA officials have said.

Ingenuity will get its chance soon. Once Perseverance gets fully up and running, the mission team will find a suitable airfield and let the helicopter fly. The rover will attempt to document these flights from a safe distance, using its cameras and microphones. 

An artist’s impression of NASA’s Mars helicopter Ingenuity. (Image credit: NASA)

Perseverance power: Its nuclear battery revealed

Spirit and Opportunity were solar powered. Both rovers far outlived their three-month warranties, roaming the red desert for years. But they both ultimately succumbed to the elements, freezing to death after finding themselves in situations where their solar panels couldn’t soak up enough sun. (NASA declared Spirit and Opportunity dead in 2011 and 2019, respectively.) 

Curiosity and Perseverance don’t have to worry about Martian sunlight levels. The big rovers are nuclear powered, each sporting a roughly 100-lb. (45 kg) Multi-Mission Radioisotope Thermoelectric Generator (MMRTG). 

These MMRTGs convert to electricity the heat naturally produced by the radioactive decay of plutonium-238. And they keep doing so for a long time; the MMRTG has an operational life of 14 years, according to NASA’s Mars 2020 information page.

Curiosity is still going strong inside Mars’ Gale Crater, more than eight years after touching down. So there’s every reason to believe that Perseverance’s power source, and its other vital components, will allow the robot to keeping roaming beyond the rover’s prime mission duration of one Mars year, or about 687 Earth days. 

Perseverance rover launch: Voyage to Mars in a pandemic

NASA’s Mars 2020 Perseverance rover and Ingenuity Mars helicopter lift off from Florida’s Cape Canaveral Air Force Station on a United Launch Alliance Atlas V rocket, on July 30, 2020. (Image credit: Joel Kowsky/NASA)

Perseverance launched from Florida’s Space Coast on July 30, 2020, hurtling into space atop a United Launch Alliance Atlas V rocket. 

Getting off Earth is never easy, and Perseverance had a particularly challenging path.  The mission team had to conduct the final assembly and testing procedures, and the launch itself, while the coronavirus pandemic raged around them.

Like the rest of us, many Perseverance team members had to adapt to working from home; key rover prep was done from living rooms, kitchens and backyard patios. And getting the robot to the launch pad on time — a high priority, since launch windows for Mars missions open for just a few weeks once every 26 months — was far from a foregone conclusion.

“In March and early April [2020], we weren’t sure we were going to be able to make it,” Jurczyk told Space.com. (Back then, the NASA administrator was Jim Bridenstine, and Jurczyk led the agency’s Space Technology Mission Directorate.) “But we were able to work through the planning and get there. It’s a real credit to the dedication and hard work of the team.”

Perseverance’s Mars landing at Jezero Crater

Perseverance’s deep-space journey went smoothly, and the rover arrived at Mars as planned, 6.5 months after liftoff. The pandemic was still an issue on landing day, however; rover team members assembled at mission control at JPL to oversee EDL on Feb. 18, but they wore masks and practiced social distancing to the extent possible.

In a harrowing “seven minutes of terror,” the rover plunged into the Martian atmosphere, jettisoned its heat shield and deployed the largest parachute ever built for Mars to slow its descent to the Martian surface. Cameras on the rover, its sky crane and backshell captured the descent down to the ground, including the moment the sky crane, hovering over the Martian surface, lowered Perseverance to the ground for a picture perfect landing. 

The Perseverance rover landed safely on Mars and began surveying its Jezero Crater home.

Image 1 of 7

NASA announced in November 2018 that Perseverance will explore Jezero Crater, one of three finalist landing sites for the Mars 2020 mission.

NASA announced in November 2018 that Perseverance will explore Jezero Crater, one of three finalist landing sites for the Mars 2020 mission. (Image credit: NASA)
Image 2 of 7

NASA's Mars 2020 will land in Jezero Crater, pictured here. The image was taken by instruments on NASA's Mars Reconnaissance Orbiter, which regularly takes images of potential landing sites for future missions.

A view of the Perseverance rover’s landing site in Jezero Crater as seen by NASA’s Mars Reconnaissance Orbiter. (Image credit: NASA/JPL-Caltech/MSSS/JHU-APL)
Image 3 of 7

This image shows the remains of an ancient delta in Jezero Crater, which NASA's Perseverance Mars rover will explore for signs of fossilized microbial life. The image was taken by the High Resolution Stereo Camera on ESA's Mars Express orbiter.

This image shows the remains of an ancient delta in Jezero Crater. It was taken by the High Resolution Stereo Camera on ESA’s Mars Express orbiter. (Image credit: ESA/DLR/FU Berlin)
Image 4 of 7

The white circle near the center of this image of Mars represents the location where NASA’s Perseverance rover is expected to land on Feb. 18, 2021. The landing ellipse, measuring 4.8 miles by 4.1 miles (7.7 kilometers by 6.6 kilometers), places the rover at the site of an ancient river delta which could harbor signs of fossilized microbial life. The fan-like shape of the delta is visible in this image, as is the crater rim. The crater was once filled with a lake several hundred feet deep. The basemap image featured here was taken by the High Resolution Stereo Camera aboard the ESA (European Space Agency) Mars Express orbiter. Light color processing has been applied to highlight surface features.

The white circle near the center of this image of Mars represents the location where NASA’s Perseverance rover is expected to land. (Image credit: ESA/DLR/FU-Berlin/NASA/JPL-Caltech)
Image 5 of 7

This annotated map of Jezero Crater on Mars was created from the red, green and blue channels of the High Resolution Stereo Camera on ESA’s Mars Express, combined with high-resolution data from its nadir channel, which is directed perpendicular to the surface of Mars.

This annotated map of Jezero Crater on Mars was created using data from the High Resolution Stereo Camera on ESA’s Mars Express orbiter. (Image credit: ESA/DLR/FU Berlin)
Image 6 of 7

This map shows regions in and around Jezero Crater on Mars, the landing site of NASA's Perseverance rover. The green circle represents the rover's landing ellipse. The map was created in a tool called Campaign Analysis Mapping and Planning (CAMP), developed by NASA's Jet Propulsion Laboratory, a division of Caltech in Southern California, which manages the Mars 2020 Perseverance rover mission for NASA's Science Mission Directorate in Washington. Data for the map was provided by the High-Resolution Imaging Science Experiment (HiRISE), one of the cameras aboard NASA's Mars Reconnaissance Orbiter, also managed by JPL. The University of Arizona, in Tucson, operates HiRISE, which was built by Ball Aerospace & Technologies Corp., in Boulder, Colorado.

This map shows regions in and around Jezero Crater on Mars. The green circle represents the rover’s landing ellipse. (Image credit: NASA/JPL-Caltech/USGS/University of Arizona)
Image 7 of 7

This elevation map of Jezero Crater on Mars was created from ESA Mars Express data.

This elevation map of Jezero Crater on Mars was created from ESA Mars Express data. (Image credit: ESA/DLR/FU Berlin)

In February 2017, a team of scientists narrowed the Mars 2020 landing-site candidates down to three finalists: Columbia Hills, Northeast Syrtis and Jezero Crater.

One site had been explored before. Starting in 2004, the Spirit rover roamed through Gusev Crater and Columbia Hills, where the robot discovered evidence of past water, the only place it found water in the enormous crater. Later data analysis suggested that the crater may have once hosted a shallow lake.

An ancient volcano in Northeast Syrtis could have generated hot springs and melting ice, creating the ideal conditions for past microbial life, researchers have said. The edge of the Syrtis Major volcano exposes 4-billion-year-old bedrock, as well as many minerals altered by volcanic activity during the Red Planet’s early history.

The 28-mile-wide (45 km) Jezero Crater, meanwhile, is an ancient lakebed where microbial life could have developed, NASA officials said in a statement. Jezero also harbors the remains of a long-gone river delta, whose structure suggests that water filled and drained from the site at least twice. MRO has also spotted minerals at the site that have been chemically altered by water.

In November 2018, NASA announced the final selection: Perseverance will explore Jezero Crater.

“The landing site in Jezero Crater offers geologically rich terrain, with landforms reaching as far back as 3.6 billion years old, that could potentially answer important questions in planetary evolution and astrobiology,” Thomas Zurbuchen, associate administrator for NASA’s Science Mission Directorate, said in a statement at the time.

“Getting samples from this unique area will revolutionize how we think about Mars and its ability to harbor life,” he added.

How the Perseverance rover will collect Mars samples

It’s possible that Perseverance will spot convincing signs of ancient life on the Martian surface — something akin to a fossilized stromatolite here on Earth, perhaps. That’s a tall order for a lonely robot on a faraway world, however, so it’s more likely that the rover’s life-hunting data will be suggestive at best, mission team members have said.

But Perseverance will allow scientists to get much better and more detailed looks at promising samples — by kicking off humanity’s first-ever Mars sample-return campaign. 

The rover will drill at least 20 rock cores, and possibly even 30 to 40. This Mars material will be secured in special sample tubes and deposited at select locations for retrieval by a joint NASA-European Space Agency campaign

“The belly of the rover houses all the equipment and supplies needed to collect samples. It contains a rotating drill carousel, which is a wheel that contains different kinds of drill bits,” NASA officials wrote in a description of Perseverance’s pioneering sample-collecting hardware.

“While the rover’s big arm reaches out and drills rock, the rover belly is home to a small robotic arm that works as a ‘lab assistant’ to the big arm,” they added. “The small arm picks up and moves new sample tubes to the drill, and transfers filled sample containers into a space where they are sealed and stored.”

If all goes according to plan, the samples will get to Earth as early as 2031. Scientists around the world will then use powerful instruments to search them for signs of life and clues about Mars’ long-ago transition from a relatively warm and wet world to the cold desert planet it is today. 

Such work will continue for decades; after all, scientists are still studying the moon rocks brought home by NASA’s Apollo astronauts half a century ago.

“Mars sample return is the planetary science endeavor of our generation,” Bobby Braun, director of solar system exploration at JPL, said during a pre-landing NASA news conference on Feb. 17.

“It’s ambitious. It’s challenging. It’s a scientifically compelling goal that, over decades, we have been working toward,” Braun said. “And it’s right there. It’s just within our reach.”

How Perseverance and Ingenuity got their names

Vaneeza Rupani, who proposed the name Ingenuity, then-NASA Administrator Jim Bridenstine, and Alex Mather, who proposed the name Perseverance, watch from NASA’s Kennedy Space Center as the Mars 2020 mission blasted off from Florida. (Image credit: NASA/Gianni Woods)

NASA let schoolkids name the Sojourner, Spirit, Opportunity and Curiosity rovers via a nationwide competition, and the agency continued this tradition with Mars 2020.

The winning name was nominated by Virginia seventh-grader Alex Mather and announced in March 2020. Mather’s essay submission ends like this: “We are a species of explorers, and we will meet many setbacks on the way to Mars. However, we can persevere. We — not as a nation but as humans — will not give up. The human race will always persevere into the future.” 

Perseverance is an especially apt name for the rover, given that the Mars 2020 team   had to deal with a global pandemic in the leadup to launch, NASA officials said.

“Yes, it’s curiosity that pulls us out there, but it’s perseverance that does not let us give up,” Zurbuchen told reporters shortly after the name was announced. “There’s no exploration without perseverance.”

Alabama high schooler Vaneeza Rupani submitted “Ingenuity” for the rover-naming contest. NASA officials liked that moniker so much that they gave it to the mission’s helicopter.

“It took a lot of hard and ingenious work to get the helicopter ready and then placed on the rover, and there’s a lot more going to be required,” Bridenstine said in an April 2020 statement. “I was happy we had another great name from the naming contest finalists from which I was able to select something so representative of this exciting part of our next mission to Mars.”

Additional resources

Follow Nola Taylor Redd on Twitter @NolaTRedd or Facebook. 

Mike Wall is the author of “Out There” (Grand Central Publishing, 2018; illustrated by Karl Tate), a book about the search for alien life. Follow him on Twitter @michaeldwall. 

Follow us on Twitter @Spacedotcom or Facebook. 

Related posts