NASA’s Mars 2020 Perseverance rover mission is getting close to its planned landing on the surface of Mars, closing in on the Red Planet at 1.6 miles per second. Once at the top of the Red Planet’s atmosphere, an action-packed seven minutes of descent awaits – complete with temperatures equivalent to the surface of the Sun, a supersonic parachute inflation, and the first ever autonomous guided landing on Mars.

“Perseverance, which was built from the collective knowledge gleaned from such trailblazers, has the opportunity to not only expand our knowledge of the Red Planet, but to investigate one of the most important and exciting questions of humanity about the origin of life both on Earth and also on other planets.”

Thomas Zurbuchen, associate administrator for NASA’s Science Mission Directorate.

Only then can the rover – the biggest, heaviest, cleanest, and most sophisticated six-wheeled robotic geologist ever launched into space – search Jezero Crater for signs of ancient life and collect samples that will eventually be returned to Earth.

“NASA has been exploring Mars since Mariner 4 performed a flyby in July of 1965, with two more flybys, seven successful orbiters, and eight landers since then,” said Thomas Zurbuchen, associate administrator for NASA’s Science Mission Directorate at the agency’s headquarters in Washington. “Perseverance, which was built from the collective knowledge gleaned from such trailblazers, has the opportunity to not only expand our knowledge of the Red Planet, but to investigate one of the most important and exciting questions of humanity about the origin of life both on Earth and also on other planets.”

Jezero Crater is the perfect place to search for signs of ancient microbial life. Billions of years ago, the now-bone-dry 28-mile-wide basin was home to an actively-forming river delta and lake filled with water. The rock and regolith (broken rock and dust) that Perseverance’s Sample Caching System collects from Jezero could help answer fundamental questions about the existence of life beyond Earth. Two future missions currently in the planning stages by NASA, in collaboration with ESA (European Space Agency), will work together to bring the samples back to Earth, where they will undergo in-depth analysis by scientists around the world using equipment far too large and complex to send to the Red Planet.

“Perseverance’s sophisticated science instruments will not only help in the hunt for fossilized microbial life, but also expand our knowledge of Martian geology and its past, present, and future,” said Ken Farley, project scientist for Mars 2020, from Caltech in Pasadena, California. “Our science team has been busy planning how best to work with what we anticipate will be a firehose of cutting-edge data. That’s the kind of ‘problem’ we are looking forward to.”

While most of the seven science instruments aboard the Perseverance rover are geared toward learning more about the planet’s geology and astrobiology, the mission also carries technologies more focused on future Mars exploration. MOXIE (Mars Oxygen In-Situ Resource Utilization Experiment), a car-battery-size device in the rover’s chassis, is designed to demonstrate that converting Martian carbon dioxide into oxygen is possible. Future applications of the technology could produce the vast quantities of oxygen that would be needed as a component of the rocket fuel astronauts would rely on to return to Earth, and, of course, the oxygen could be used for breathing as well.

The Terrain-Relative Navigation system aboard the Perseverance rover helps the vehicle avoid hazards. MEDLI2 (the Mars Entry, Descent, and Landing Instrumentation 2) sensor suite gathers data during the journey through the Martian atmosphere. Together the systems will help engineers design future human missions that can land more safely and with larger payloads on other worlds.

Another technology demonstration, the Ingenuity Mars Helicopter, is attached to the belly of the rover. Between 30 and 90 days into the rover’s mission, Ingenuity will be deployed to attempt the first experimental flight test on another planet. If that initial flight is successful, Ingenuity will fly up to four more times. The data acquired during these tests will help the next generation of Mars helicopters provide an aerial dimension to Mars exploration.

Like people around the world, members of the Mars 2020 team have had to make significant modifications to their approach to work during the COVID-19 pandemic. While a majority of the team members have performed their jobs via telework, some tasks have required an in-person presence at NASA’s Jet Propulsion Laboratory, which built the rover for the agency and is managing the mission. Such was the case last week when the team that will be on-console at JPL during landing went through a three-day-long COVID-adapted full-up simulation of the upcoming Feb. 18 Mars landing.

“Don’t let anybody tell you different – landing on Mars is hard to do,” said John McNamee, project manager for the Mars 2020 Perseverance rover mission at JPL. “But the women and men on this team are the best in the world at what they do. When our spacecraft hits the top of the Mars atmosphere at about three-and-a-half miles per second, we’ll be ready.”

Less than a month of dark, unforgiving interplanetary space remains before the landing. NASA Television and the agency’s website will carry live coverage of the event from JPL beginning at 11:15 a.m. PST (2:15 p.m. EST).

(Image and video provided with NASA news release)