NASA’s Perseverance Rover Begins Its First Science Campaign on Mars

The six-wheeled scientist is heading south to explore Jezero Crater’s lakebed in search of signs of ancient microbial life.

On June 1, NASA’s Perseverance Mars rover kicked off the science phase of its mission by leaving the “Octavia E. Butler” landing site. Until recently, the rover has been undergoing systems tests, or commissioning, and supporting the Ingenuity Mars Helicopter’s month of flight tests.

During the first few weeks of this first science campaign, the mission team will drive to a low-lying scenic overlook from which the rover can survey some of the oldest geologic features in Jezero Crater, and they’ll bring online the final capabilities of the rover’s auto-navigation and sampling systems.

By the time Perseverance completed its commissioning phase on June 1, the rover had already tested its oxygen-generating MOXIE instrument and conducted the technology demonstration flights of the Ingenuity helicopter. Its cameras had taken more than 75,000 images, and its microphones had recorded the first audio soundtracks of Mars.

“We are putting the rover’s commissioning phase as well as the landing site in our rearview mirror and hitting the road,” said Jennifer Trosper, Perseverance project manager at NASA’s Jet Propulsion Laboratory in Southern California. “Over the next several months, Perseverance will be exploring a 1.5-square-mile [4-square-kilometer] patch of crater floor. It is from this location that the first samples from another planet will be collected for return to Earth by a future mission.”

The science goals of the mission are to study the Jezero region in order to understand the geology and past habitability of the environment in the area, and to search for signs of ancient microscopic life. The team will identify and collect the most compelling rock and sediment samples, which a future mission could retrieve and bring back to Earth for more detailed study. Perseverance will also take measurements and test technologies to support future human and robotic exploration of Mars.

Unique Geology

Spanning hundreds of sols (or Martian days), this first science campaign will pursue all of the mission’s science goals as the rover explores two unique geologic units in which Jezero’s deepest (and most ancient) layers of exposed bedrock and other intriguing geologic features can be found. The first unit, called “the Crater Floor Fractured Rough,” is the crater-filled floor of Jezero. The adjacent unit, named “Séítah” (meaning “amidst the sand” in the Navajo language), has its fair share of Mars bedrock but is also home to ridges, layered rocks, and sand dunes.

“To do justice to both units in the time allotted, the team came up with the Martian version of an old auto club-style map,” said JPL’s Kevin Hand, an astrobiologist and co-lead, along with Vivian Sun, of this science campaign. “We have our route planned, complete with optional turnoffs and labeled areas of interest and potential obstructions in our path.”

Most of the challenges along the way are expected to come in the form of sand dunes located within the mitten-shaped Séítah unit. To negotiate them, the rover team decided Perseverance will drive mostly either on the Crater Floor Fractured Rough or along the boundary line between it and Séítah. When the occasion calls for it, Perseverance will perform a “toe dip” into the Séítah unit, making a beeline for a specific area of interest.

The goal of the campaign is to establish what four locations in these units best tell the story of Jezero Crater’s early environment and geologic history. When the science team decides a location is just right, they will collect one or two samples.

“Starting with the Crater Floor Fractured Rough and Seitah geologic units allows us to start our exploration of Jezero at the very beginning,” said Hand. “This area was under at least 100 meters [328 feet] of water 3.8 billion years ago. We don’t know what stories the rocks and layered outcrops will tell us, but we’re excited to get started.”

The first science campaign will be complete when the rover returns to its landing site. At that point, Perseverance will have traveled between 1.6 and 3.1 miles (2.5 and 5 kilometers) and up to eight of Perseverance’s 43 sample tubes could be filled with Mars rock and regolith (broken rock and dust). Next, Perseverance will travel north then west toward the location of its second science campaign: Jezero’s delta region. The delta is the fan-shaped remains of the confluence of an ancient river and a lake within Jezero Crater. The location may be especially rich in carbonates – minerals that, on Earth, can preserve fossilized signs of ancient life and can be associated with biological processes.

The start of Perseverance’s first science campaign also marks a transition on the team: On June 7, Jennifer Trosper became the mission’s new project manager. She succeeds Matt Wallace, who is moving on to become JPL’s Deputy Director for Planetary Science.

“From Sojourner to Spirit and Opportunity to Curiosity to Perseverance, Matt has played key roles in the design, construction, and operations of every Mars rover NASA has ever built,” said Trosper. “And while the project is losing a great leader and trusted friend, we know Matt will continue making great things happen for the planetary science community.”

More About the Mission

A key objective for Perseverance’s mission on Mars is astrobiology, including the search for signs of ancient microbial life. The rover will characterize the planet’s geology and past climate, pave the way for human exploration of the Red Planet, and be the first mission to collect and cache Martian rock and regolith.

Subsequent NASA missions, in cooperation with ESA (European Space Agency), would send spacecraft to Mars to collect these sealed samples from the surface and return them to Earth for in-depth analysis.

The Mars 2020 Perseverance mission is part of NASA’s Moon to Mars exploration approach, which includes Artemis missions to the Moon that will help prepare for human exploration of the Red Planet.

JPL, which is managed for NASA by Caltech in Pasadena, California, built and manages operations of the Perseverance rover.

For more about Perseverance:

mars.nasa.gov/mars2020/

nasa.gov/perseverance

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See the First Images NASA’s Juno Took As It Sailed by Ganymede

The spacecraft flew closer to Jupiter’s largest moon than any other in more than two decades, offering dramatic glimpses of the icy orb.

The first two images from NASA Juno’s June 7, 2021, flyby of Jupiter’s giant moon Ganymede have been received on Earth. The photos – one from the Jupiter orbiter’s JunoCam imager and the other from its Stellar Reference Unit star camera – show the surface in remarkable detail, including craters, clearly distinct dark and bright terrain, and long structural features possibly linked to tectonic faults.

“This is the closest any spacecraft has come to this mammoth moon in a generation,” said Juno Principal Investigator Scott Bolton of the Southwest Research Institute in San Antonio. “We are going to take our time before we draw any scientific conclusions, but until then we can simply marvel at this celestial wonder – the only moon in our solar system bigger than the planet Mercury.”

Using its green filter, the spacecraft’s JunoCam visible-light imager captured almost an entire side of the water-ice-encrusted moon. Later, when versions of the same image come down incorporating the camera’s red and blue filters, imaging experts will be able to provide a color portrait of Ganymede. Image resolution is about 0.6 miles (1 kilometer) per pixel.

In addition, Juno’s Stellar Reference Unit, a navigation camera that keeps the spacecraft on course, provided a black-and-white picture of Ganymede’s dark side (the side opposite the Sun) bathed in dim light scattered off Jupiter. Image resolution is between 0.37 to 0.56 miles (600 to 900 meters) per pixel.

“The conditions in which we collected the dark side image of Ganymede were ideal for a low-light camera like our Stellar Reference Unit,” said Heidi Becker, Juno’s radiation monitoring lead at JPL. “So this is a different part of the surface than seen by JunoCam in direct sunlight. It will be fun to see what the two teams can piece together.”

The spacecraft will send more images from its Ganymede flyby in the coming days, with JunoCam’s raw images being made available here.

The solar-powered spacecraft’s encounter with the Jovian moon is expected to yield insights into its composition, ionosphere, magnetosphere, and ice shell while also providing measurements of the radiation environment that will benefit future missions to the Jovian system.

More About the Mission

JPL, a division of Caltech in Pasadena, California, manages the Juno mission for the principal investigator, Scott J. Bolton, of the Southwest Research Institute in San Antonio. Juno is part of NASA’s New Frontiers Program, which is managed at NASA’s Marshall Space Flight Center in Huntsville, Alabama, for the agency’s Science Mission Directorate in Washington. Lockheed Martin Space in Denver built and operates the spacecraft.

More information about Juno is available at:

https://www.nasa.gov/juno

https://www.missionjuno.swri.edu

Follow the mission on Facebook and Twitter at:

https://www.facebook.com/NASASolarSystem

https://www.twitter.com/NASASolarSystem

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 Meet 'Zhurong': China names Tianwen-1 Mars rover ahead of mid-May landing attempt

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China has named its first-ever Mars rover "Zhurong" after an ancient fire god ahead of a landing attempt on the Red Planet in May.

The China National Space Administration (CNSA) revealed the name at the sixth China Space Day held in Nanjing on Saturday (April 24).

Zhurong was the most popular of 10 shortlisted names for a public vote that opened in January, and that choice was backed by an expert panel and the CNSA itself.

The roughly 530-lb. (240 kilograms) solar-powered Zhurong rover is part of the Tianwen-1 mission, which launched in July 2020 and arrived in orbit around Mars in February.

The Tianwen-1 orbiter has been collecting high-resolution images of Zhurong’s target landing site in Utopia Planitia. The landing attempt is expected in mid-May, according to a senior Chinese space scientist.

The rover carries panoramic and multispectral cameras and instruments to analyze the composition of rocks. Zhurong will also investigate subsurface characteristics with ground-penetrating radar, if all goes according to plan.

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