NASA's Perseverance rover finds organic chemicals on Mars
It's not a detection of Mars life, but it's certainly intriguing.
A selfie snapped by NASA's Perseverance Mars rover, which has been exploring the Red Planet's Jezero Crater since February 2021.(Image credit: NASA/JPL-Caltech/MSSS)
NASA's Perseverance Mars rover has found life's building blocks on the Red Planet.
Perseverance has identified carbon-containing organic chemicals in some of the rocks it has examined on the floor of Mars' Jezero Crater, mission team members announced on Wednesday (Dec. 15).
To be clear: This is not a detection of Mars life. Organics can be produced by both biological and non-biological means, and more work is needed to figure out what processes generated the Jezero compounds.
Perseverance won't have to do all that work by itself; the rover is collecting samples that will be hauled to Earth by a joint NASA/European Space Agency campaign, perhaps as early as 2031.
"This is a question that may not be solved until the samples are returned to Earth, but the preservation of organics is very exciting," Luther Beegle, of NASA's Jet Propulsion Laboratory (JPL) in Southern California, said in a statement.
"When these samples are returned to Earth, they will be a source of scientific inquiry and discovery for many years," added Beegle, the principal investigator of Perseverance's SHERLOC ("Scanning Habitable Environments with Raman and Luminescence for Organics and Chemicals") instrument.
Studying a potentially habitable ancient environment
The car-sized Perseverance landed last February inside the 28-mile-wide (45 kilometers) Jezero, which hosted a big lake and a river delta in the ancient past.
Perseverance has two main mission goals: search for signs of ancient life on Mars and collect the material for humanity's first Mars sample-return effort. Toward this latter end, the rover carries 43 titanium tubes, six of which it has sealed to date. Four of the sealed tubes contain cored rock samples, one has a sample of Martian atmosphere and one harbors "witness" material to help mission team members spot any contaminating compounds that Perseverance may have brought from Earth, JPL officials said in the same statement.
Perseverance spent its first few months on Mars checking out its instruments and systems and supporting the initial pioneering flights of the Ingenuity helicopter, which landed with the rover in February. Perseverance began focusing on its science goals in early June, and it has made quite a bit of progress since then.
There's the organics find, for example, which mission team members unveiled Wednesday at the fall meeting of the American Geophysical Union in New Orleans.
SHERLOC identified organics in the interiors of some rocks that Perseverance abraded with its drill and also in dust on top of some non-abraded rocks, JPL officials said in Wednesday's statement.
"Curiosity also discovered organics at its landing site within Gale Crater," Beegle said, referring to NASA's Curiosity rover, which has been exploring the 96-mile-wide (154 km) Gale since August 2012.
"What SHERLOC adds to the story is its capability to map the spatial distribution of organics inside rocks and relate those organics to minerals found there," he added. "This helps us understand the environment in which the organics formed."
This graphic depicts the Perseverance Mars rover's entry into the "Séítah" region of Jezero Crater from both an orbital and subsurface perspective. The lower image is a subsurface "radargram" from the rover’s RIMFAX instrument; the red lines indicate link subsurface features to erosion-resistant rocky outcrops visible above the surface. (Image credit: NASA/JPL-Caltech/University of Arizona/USGS/FFI)
Ancient volcanic activity, too
Another Perseverance instrument, PIXL ("Planetary Instrument for X-ray Lithochemistry"), is bringing that ancient environment into clearer focus as well. PIXL analyses of an abraded rock in a patch of Jezero called South Séítah revealed a striking abundance of olivine crystals in conjunction with pyroxene crystals, mission team members announced on Wednesday.
"A good geology student will tell you that such a texture indicates the rock formed when crystals grew and settled in a slowly cooling magma — for example, a thick lava flow, lava lake or magma chamber," Perseverance project scientist Ken Farley, of the California Institute of Technology in Pasadena, said in the same statement.
"The rock was then altered by water several times, making it a treasure trove that will allow future scientists to date events in Jezero, better understand the period in which water was more common on its surface and reveal the early history of the planet," Farley said. "Mars sample return is going to have great stuff to choose from!"
Farley and his colleagues have long wondered whether Jezero's bedrock is volcanic or sedimentary (composed of material deposited by an ancient river, for example). They now appear to have the answer, but there are still more layers to peel back. For example, was the molten rock part of a lava lake on the crater's floor? Or did it form in an underground magma chamber, which erosion has since exposed?
Perseverance could help solve that puzzle and many others over the months and years to come as it continues to take Jezero's measure.
Some of those insights will extend into the Martian underground. Also on Wednesday, the mission team released its first Perseverance "radargram," a snapshot of the subsurface up to 33 feet (10 meters) deep created using data from the rover's ground-penetrating radar instrument.
"The ability to observe geologic features even below the surface adds a new dimension to the team's geologic mapping capabilities at Mars," JPL officials said in the statement.
Quelle: SC
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NASA's Mars helicopter Ingenuity passes 30 minutes of total air time
The helicopter finished its 17th flight on Dec. 5, and is getting ready for an 18th as soon as Wednesday (Dec. 15).
The first Martian drone has reached the 30 minute air time mark.
After a 117-second Mars sortie on Dec. 5, the total flight time for the Ingenuity helicopter is 30 minutes and 48 seconds after 17 total flights, NASA's Jet Propulsion Laboratory said in a statement on Wednesday (Dec. 15).
There was a delay in releasing the results due to a technical glitch, JPL noted, due to an "unexpected cutoff to the in-flight data stream as the helicopter descended toward the surface at the conclusion of its flight."
While JPL did get a handful of data packets almost immediately showing the drone was probably doing just fine, it was only on a downlink from Mars Dec. 10 that enough data came through to indicate Flight 17 was successful.
"Ingenuity is in excellent condition," JPL stated, which put the little drone at a go for making its 18th flight this week. Ingenuity, which landed on Mars with NASA's Perseverance rover in February, has been battling normal seasonal changes in the atmosphere that require its rotor to spin a little faster against thinner air, which appears to be working well so far.
The flight plan for No. 18 will see Ingenuity fly 754 feet (230 meters) and reach a top speed of 5.6 mph (9 kph) over 125 seconds. This will bring the helicopter to a new airfield, near the northern boundary of a region named Séítah.
Ingenuity's radio range and performance will be tested to an extreme degree on this flight, and as such, engineers decided to have the helicopter communicate back to the Perseverance rover using a low data-rate mode.
"If we do lose radio link on landing, it may be several days or weeks until the line-of-sight between Ingenuity and Perseverance improves enough to attempt a communication session," Teddy Tzanetos, Ingenuity team lead, said in the same statement.
"While delaying our post-flight data analysis is an inconvenience, it is not unexpected and becoming the new normal as we continue to operate in challenging terrain in the weeks ahead."
Quelle: SC
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Update: 7.01.2022
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Mars helicopter Ingenuity gearing up for 19th Red Planet flight on Friday
The flight will be short but challenging.
The targeted landing zone for Ingenuity’s 19th Mars flight can be seen in this image, which the helicopter captured during its ninth sortie on July 5, 2021. The targeted landing spot is in the center of the image, just below the Perseverance rover tracks.(Image credit: NASA/JPL-Caltech)
NASA's Mars helicopter Ingenuity is poised to make its first flight of 2022.
The 4-pound (1.8 kilograms) Ingenuity's next Red Planet sortie — its 19th overall — will take place as early as Friday (Jan. 7), mission team members said in a blog post on Tuesday (Jan. 4).
Ingenuity will cover 207 feet (63 meters) during the 100-second flight, which will take the little chopper out of a rugged basin known as South Séítah, over a ridge and onto a plateau.
"While short, the flight has a challenging start due to featureless sandy terrain that the helicopter currently sits on," Martin Cacan, Ingenuity pilot at NASA's Jet Propulsion Laboratory in Southern California, wrote in the blog post.
"Initially chosen for the lack of rocks to land safely, the area is actually so devoid of rock that warnings were reported during Flight 18 landing due to insufficient features to track in the vision navigation," Cacan wrote. "As a result, fault protection parameters will be updated to mitigate the risk of a premature landing mid-ascent."
Ingenuity landed on the floor of Mars' Jezero Crater with NASA's Perseverance rover on Feb. 18, 2021. The little rotorcraft soon aced five technology-demonstrating flights, showing that aerial exploration is possible on Mars despite the planet's thin atmosphere. Ingenuity then moved into an extended mission during which team members are pushing its limits and scouting Jezero terrain for the life-hunting, sample-caching Perseverance.
Jezero harbored a big lake and a river delta billions of years ago. The Perseverance team is keen to check out the remnants of that delta, which could potentially preserve signs of Mars life, if any ever existed. And Ingenuity will help the rover make its way there, if all goes according to plan.
"The current mission goal is to reach the Jezero river delta to aid the Perseverance rover in path planning and scientific discovery," Cacan wrote.
Ingenuity has conducted 18 flights on Mars to date, the first occurring on April 19 and the most recent on Dec. 15. During these sorties, the helicopter has stayed aloft for nearly 33 minutes in total and covered 2.37 miles (3.81 kilometers) of Red Planet ground.
Quelle:SC
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Update: 9.01.2022
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NASA Perseverance Mars rover has crud obstructing its rock sample system
Some pesky pebbles are putting a crimp in Perseverance's sampling activities, but NASA is working on a solution.
This image from Jan. 7 shows the debris obstructing the bit carousel on NASA's Perseverance rover.
NASA/JPL-Caltech/MSSS
Mars does not take kindly to our robotic explorers. It chokes them with dust, roughs up their wheels and messes with their probes, and now it's throwing a new challenge at NASA's Perseverance rover. There's some pebble-size debris getting in the way of the machine's rock sample collection system.
Everything went smoothly at first. On Dec. 29, Perseverance drilled into a rock nicknamed Issole and extracted a sample of it. "However, during the transfer of the bit that contains the sample into the rover's bit carousel (which stores bits and passes tubes to the tube processing hardware inside the rover), our sensors indicated an anomaly," wrote Louise Jandura, chief engineer for sampling and caching, in a blog post on Friday.
The rover halted its sampling activities when it met unusual resistance during the process of stowing the sample. As the rover team expressed in a tweet on Friday, the upshot is the debris is preventing the rover's robotic arm from properly handing off the sample-filled tube for sealing and storage.
Perseverance is the first rover to attempt to collect samples of Mars in sealed tubes. It's a key part of a mission that's also seeking out signs of ancient microbial life on the red planet. NASA is planning to send an ambitious future mission to pick up the samples and bring them back to Earth for study.
The rover team commanded the machine to backtrack by pulling out the drill bit and tube. It snapped some images along the way to help diagnose the problem. "These most recent downlinked images confirm that inside the bit carousel there are a few pieces of pebble-sized debris," Jandura wrote. NASA expects the pebbles fell out of the sample tube.
Quelle: Cnet
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Update: 13.01.2022
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Perseverance rover chokes on Mars pebbles while collecting 6th rock sample
The mission team is working to clear the debris.
This image of pebble-size debris in the bit carousel on NASA’s Perseverance Mars rover was acquired on Jan. 7, 2022, by the rover's WATSON camera. The image was taken to assist the Perseverance team in diagnosing an anomaly that occurred during a rock sampling on Dec. 29, 2021.(Image credit: NASA/JPL-Caltech/MSSS)
NASA's Perseverance Mars rover has some rocks stuck in its throat.
Perseverance drilled and collected its sixth Red Planet rock sample late last month, but the car-sized rover hasn't been able to seal up the titanium tube containing the material yet.
"I recently captured my sixth rock core and have encountered a new challenge. Seems some pebble-sized debris is obstructing my robotic arm from handing off the tube for sealing/storage. More images and data to come. #SamplingMars takes perseverance," mission team members said on Friday (Jan. 7) via Perseverance's Twitter account.
Perseverance landed in February 2021 inside the 28-mile-wide (45 kilometers) Jezero Crater, which harbored a lake and river delta billions of years ago. The rover has two main mission goals: hunt for signs of ancient Mars life and collect and cache several dozen samples. This pristine Martian material will be returned to Earth, perhaps as early as 2031, by a joint NASA/European Space Agency campaign.
Perseverance has already socked away five Red Planet rock samples. On Dec. 29, the six-wheeled robot collected sample number six from a rock the mission team calls Issole, coring the material out using the percussive drill at the end of its 7-foot-long (2.1 meters) robotic arm.
Everything went smoothly until Perseverance transferred the sample, which was already inside its titanium tube, into the "bit carousel," a rotating, wheel-like structure on the rover's chassis. Sensors recorded resistance unexpectedly early during this step, suggesting a blockage of some sort.
Late last week, the mission team instructed Perseverance to remove the sample-filled tube from the carousel and take some photos of the mechanism. Those images revealed pebbles in the bit carousel.
The Perseverance team is working through the issue now.
"The designers of the bit carousel did take into consideration the ability to continue to successfully operate with debris," Louise Jandura, chief engineer for sampling and caching at NASA's Jet Propulsion Laboratory in Southern California, which manages Perseverance's mission, wrote in a blog post on Friday (Jan. 7).
"However, this is the first time we are doing a debris removal, and we want to take whatever time is necessary to ensure these pebbles exit in a controlled and orderly fashion," Jandura added.
This isn't the first sampling challenge that Perseverance has faced on Mars. For example, the rover failed to collect any material during its first sampling effort, which took place in August. The mission team determined that the target rock on that occasion was likely too soft, crumbling to bits that didn't make it into the tube.
"One thing we've found is that when the engineering challenge is hundreds of millions of miles away (Mars is currently 215 million miles [346 million kilometers] from Earth), it pays to take your time and be thorough," Jandura wrote. "We are going to do that here. So that when we do hit the unpaved Martian road again, Perseverance sample collection is also ready to roll."
Quelle: SC
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Update: 17.01.2022
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Pebbles Before Mountains
Mars Perseverance Sol 320 - WATSON Image: NASA's Mars Perseverance rover acquired this image using its onboard SHERLOC WATSON imager. The camera is located on the turret at the end of the rover's robotic arm. The image was acquired on Jan. 13, 2022 (Sol 320). Credits: NASA/JPL-Caltech. Download image ›
NASA’s Mars 2020 mission team has been working methodically and thoroughly, making good progress on understanding the best path forward to remove the uninvited pebbles from Perseverance’s bit carousel. Over the previous weekend, and earlier this week, operational sequences were developed and tested to remove these rocky interlopers.
With terrestrial experimentation complete, we have begun executing our mitigation strategy on Mars. On Jan. 12 we did a detailed image survey of the ground below Perseverance. This was done so we would have a good idea what rocks and pebbles already exist down there before some more – from our bit carousel – join them in the not-so-distant future.
With this below-chassis, preliminary imaging, in hand, the team embarked on a maneuver with our robotic arm I never imagined we would perform – ever. Simply put, we are returning the remaining contents of Sample Tube 261 (our latest cored-rock sample) back to its planet of origin. Although this scenario was never designed or planned for prior to launch, it turns out dumping a core from an open tube is a fairly straightforward process (at least during Earth testing). We sent commands up yesterday, and later on today the rover’s robotic arm will simply point the open end of the sample tube toward the surface of Mars and let gravity do the rest.
I imagine your next question is, “Why are you dumping out the contents of the sample tube?” The answer is that, at present, we are not certain how much cored rock continues to reside in Tube 261. And while this rock will never make my holiday card list, the science team really seems to like it. So if our plans go well with our pebble mitigation (see below), we may very well attempt to core “Issole” (the rock from which this sample was taken) again.
Which brings me to next steps in our pebble mitigation strategy: we’re sending up commands to the rover later today, ordering it to do two rotation tests of the bit carousel. These tests (the first, a small rotation; the second, larger) will execute this weekend. Our expectations are that these rotations – and any subsequent pebble movement – will help guide our team, providing them the necessary information on how to proceed. Still, to be thorough, we are also commanding the rover to take a second set of under-chassis images, just in case one or more pebbles happen to pop free.
We expect the data and imagery from these two rotation tests to be sent to Earth by next Tuesday, Jan. 18. From there, we’ll analyze and further refine our plans. If I had to ballpark it, I would estimate we’ll be at our current location another week or so – or even more if we decide to re-sample Issole.
So there you have it. The Perseverance team is exploring every facet of the issue to ensure that we not only get rid of this rocky debris but also prevent a similar reoccurrence during future sampling. Essentially, we are leaving no rock unturned in the pursuit of these four pebbles.
Quelle: NASA
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Update: 19.01.2022
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NASA’s Curiosity Rover Measures Intriguing Carbon Signature on Mars
NASA's Curiosity Mars rover captured these clouds just after sunset on March 19, 2021, the 3,063rd Martian day, or sol, of the rover's mission. The image is made up of 21 individual images stitched together and color corrected so that the scene appears as it would to the human eye. The clouds are drifting over "Mont Mercou," a cliff face that Curiosity has been studying.
The rover captured the image using its Mast Camera, or Mastcam. Malin Space Science Systems in San Diego built and operates Mastcam. A division of Caltech, NASA's Jet Propulsion Laboratory in Southern California built the Curiosity rover and manages the Curiosity rover for the agency's Science Mission Directorate in Washington.
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The type of carbon is associated with biological processes on Earth. Curiosity scientists offer several explanations for the unusual carbon signals.
After analyzing powdered rock samples collected from the surface of Mars by NASA’s Curiosity rover, scientists have announced that several of the samples are rich in a type of carbon that on Earth is associated with biological processes.
While the finding is intriguing, it doesn’t necessarily point to ancient life on Mars, as scientists have not yet found conclusive supporting evidence of ancient or current biology there, such as sedimentary rock formations produced by ancient bacteria, or a diversity of complex organic molecules formed by life.
“We’re finding things on Mars that are tantalizingly interesting, but we would really need more evidence to say we’ve identified life,” said Paul Mahaffy, who served as the principal investigator of the Sample Analysis at Mars (SAM) chemistry lab aboard Curiosity until retiring from NASA’s Goddard Space Flight Center in Greenbelt, Maryland, in December 2021. “So we’re looking at what else could have caused the carbon signature we’re seeing, if not life.”
In a report of their findings to be published in the Proceedings of the National Academy of Sciences journal on Jan. 18, Curiosity scientists offer several explanations for the unusual carbon signals they detected. Their hypotheses are drawn partly from carbon signatures on Earth, but scientists warn the two planets are so different they can’t make definitive conclusions based on Earth examples.
“The hardest thing is letting go of Earth and letting go of that bias that we have and really trying to get into the fundamentals of the chemistry, physics, and environmental processes on Mars,” said Goddard astrobiologist Jennifer L. Eigenbrode, who participated in the carbon study. Previously, Eigenbrode led an international team of Curiosity scientists in the detection of myriad organic molecules – ones that contain carbon – on the Martian surface.
“We need to open our minds and think outside the box,” Eigenbrode said, “and that’s what this paper does.”
The biological explanation Curiosity scientists present in their paper is inspired by Earth life. It involves ancient bacteria in the surface that would have produced a unique carbon signature as they released methane into the atmosphere where ultraviolet light would have converted that gas into larger, more complex molecules. These new molecules would have rained down to the surface and now could be preserved with their distinct carbon signature in Martian rocks.
Two other hypotheses offer nonbiological explanations. One suggests the carbon signature could have resulted from the interaction of ultraviolet light with carbon dioxide gas in the Martian atmosphere, producing new carbon-containing molecules that would have settled to the surface. And the other speculates that the carbon could have been left behind from a rare event hundreds of millions of years ago when the solar system passed through a giant molecular cloud rich in the type of carbon detected.
“All three explanations fit the data,” said Christopher House, a Curiosity scientist based at Pennsylvania State University who led the carbon study. “We simply need more data to rule them in or out.”
To analyze carbon in the Martian surface, House’s team used the Tunable Laser Spectrometer (TLS) instrument inside the SAM lab. SAM heated 24 samples from geologically diverse locations in the planet’s Gale Crater to about 1,500 degrees Fahrenheit, or 850 degrees Celsius, to release the gases inside. Then the TLS measured the isotopes from some of the reduced carbon that was set free in the heating process. Isotopes are atoms of an element with different masses due to their distinct number of neutrons, and they are instrumental in understanding the chemical and biological evolution of planets.
Carbon is particularly important since this element is found in all life on Earth; it flows continuously through the air, water, and ground in a cycle that’s well understood thanks to isotope measurements.
For instance, living creatures on Earth use the smaller, lighter carbon-12 atom to metabolize food or for photosynthesis versus the heavier carbon-13 atom. Thus, significantly more carbon-12 than carbon-13 in ancient rocks, along with other evidence, suggests to scientists they’re looking at signatures of life-related chemistry. Looking at the ratio of these two carbon isotopes helps Earth scientists tell what type of life they’re looking at and the environment it lived in.
On Mars, Curiosity researchers found that nearly half of their samples had surprisingly large amounts of carbon-12 compared to what scientists have measured in the Martian atmosphere and meteorites. These samples came from five distinct locations in Gale Crater, the researchers report, which may be related in that all the locations have well-preserved, ancient surfaces.
“On Earth, processes that would produce the carbon signal we’re detecting on Mars are biological,” House said. “We have to understand whether the same explanation works for Mars, or if there are other explanations, because Mars is very different.”
Mars is unique because it may have started off with a different mix of carbon isotopes than Earth 4.5 billion years ago. Mars is smaller, cooler, has weaker gravity, and different gases in its atmosphere. Additionally, the carbon on Mars could be cycling without any life involved.
“There’s a huge chunk of the carbon cycle on Earth that involves life, and because of life, there is a chunk of the carbon cycle on Earth we can’t understand, because everywhere we look there is life,” said Andrew Steele, a Curiosity scientist based at the Carnegie Institution for Science in Washington, D.C.
Steele noted that scientists are in the early stages of understanding how carbon cycles on Mars and, thus, how to interpret isotopic ratios and the nonbiological activities that could lead to those ratios. Curiosity, which arrived on the Red Planet in 2012, is the first rover with tools to study carbon isotopes in the surface. Other missions have collected information about isotopic signatures in the atmosphere, and scientists have measured ratios of Martian meteorites that have been collected on Earth.
“Defining the carbon cycle on Mars is absolutely key to trying to understand how life could fit into that cycle,” Steele said. “We have done that really successfully on Earth, but we are just beginning to define that cycle for Mars.”
Curiosity scientists will continue to measure carbon isotopes to see if they get a similar signature when the rover visits other sites suspected to have well-preserved ancient surfaces. To further test the biological hypothesis involving methane-producing microorganisms, the Curiosity team would like to analyze the carbon content of a methane plume released from the surface. The rover unexpectedly encountered such a plume in 2019 but there’s no way to predict whether that will happen again. Otherwise, researchers point out that this study provides guidance to the team behind NASA’s Perseverance rover on the best types of samples to collect to confirm the carbon signature and determine definitively whether it’s coming from life or not. Perseverance is collecting samples from the Martian surface for possible future return to Earth.
Curiosity’s mission is led by NASA’s Jet Propulsion Laboratory in Southern California; JPL is managed by Caltech.
Quelle: NASA
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Update: 3.02.2022
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Mars rover Perseverance collects new sample after clearing pebble clog
Perseverance is back in sampling action.
NASA’s Mars rover Perseverance captured this image of a recently collected sample using its Mastcam-Z camera on Jan. 31, 2022.(Image credit: NASA/JPL-Caltech/ASU)
NASA's Mars rover Perseverance has snagged a sample to replace the material that got stuck in its throat.
Perseverance drilled into a rock called Issole on Dec. 29, 2021, collecting its sixth cored sample since touching down inside the Red Planet's Jezero Crater last February. But the car-sized rover couldn't seal up the titanium tube as planned, a problem the mission team soon traced to a few meddlesome pebbles clogging up Perseverance's sample-handling system.
Perseverance dumped the rock core out in mid-January and shook the pebbles free last week. Those activities cleared the way for the next sample-collecting effort, which the six-wheeled robot just pulled off back at Issole.
NASA's Mars rover Perseverance captured this photo of the recently drilled rock known as Issole using its Mastcam-Z camera system on Jan. 29, 2022. (Image credit: NASA’s Mars rover Perseverance captured this image of a recently collected sample using its Mastcam-Z camera on Jan. 31, 2022.)
"This rock almost looked surprised that I was coming back! Thankfully, I was able to collect another sample here to replace the one I discarded earlier. This may be one of the oldest rocks I sample, so it could help us understand the history of this place. #SamplingMars," mission team members wrote Monday (Jan. 31) via Perseverance's official Twitter account.
The Twitter post included photos of poor pockmarked Issole and a shot of the newly collected rock core.
Gathering such samples is one of Perseverance's two main mission goals, along with searching for signs of past Mars life inside Jezero. The mission team aims to ultimately collect several dozen samples, which will be returned to Earth, perhaps as early as 2031, by a joint NASA-European Space Agency campaign.
Jezero is a great place to do such work, scientists and NASA officials have said, because the crater harbored a lake and a river delta billions of years ago. Petrified remnants of that delta still exist on Jezero's floor, and the mission team is eager to explore and sample those ancient pieces.
Perseverance has already begun making long-distance observations of the delta to help prepare for those activities, rover team member Eleni Ravanis wrote in a blog post on Monday. But the rover won't start trekking there just yet, added Ravanis, who's a Perseverance student collaborator at the University of Hawai'i at Mānoa. It will first study a nearby site known as Rimplas and may also drill a few cores in the area, including from Roubion, the first Red Planet rock that Perseverance tried to sample. That attempt, in August 2021, failed because the rock unexpectedly crumbled to bits when the rover drilled into it.
"These decisions, as all decisions on a mission as complex and ambitious as Mars 2020, will be a tradeoff between sols (the Martian days we'll spend) and the expected science return," Ravanis wrote, referring to the official name of Perseverance's mission.
"We'll then begin a multi-[kilometer] drive aimed at reaching the delta as soon as possible. Along the way, science observations may include investigations of the craters we pass throughout our journey to the delta," Ravanis added. "This could be particularly useful for understanding the sequence of events at Jezero Crater, which may be revealed in exposures along the crater walls."
Quelle: SC
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Update: 7.02.2022
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Why Mars helicopters like Ingenuity could glow in the dark
You can blame dust in the wind.
Artist's impression of a Martian drone with a glow around its rotors; at back is a Perseverance-like rover.(Image credit: NASA/Jay Friedlander)
Helicopters making dusk flights on Mars might glow in the dark.
A new study suggests that Mars drones, such as the Ingenuity helicopter making periodic sorties on the Red Planet, "may cause tiny electric currents to flow in the Martian atmosphere," according to NASA.
The potential currents are not a threat to the helicopter, if they do indeed arise in the first place, but would create an interesting effect for any cameras that are nearby. More broadly, the study provides an avenue to better understand the accumulation of electric charge on rotor blades, known as "triboelectric charging."
"The faint glow would be most visible during evening hours when the background sky is darker," study lead author Bill Farrell, a plasma scientist at NASA's Goddard Space Flight Center in Maryland, said in the same statement. Regretfully, he added, Ingenuity is an experimental drone not cleared to fly at dusk or dawn, but we might be able to observe the effect on future Martian helicopters.
The process by which Martian drones might glow is similar to common effects on Earth from electrical currents, including corona or electrical glow sometimes seen on aircraft, along with ships in electrical storms known as St. Elmo's Fire, NASA said.
Triboelectric charging occurs during friction that moves electrical charge between objects, which you can commonly see when a person rubs a balloon against their hair on Earth. The balloon then "attracts" the person's hair, showing evidence of the electric field induced by the rubbing.
Laboratory measurements and computer models suggest that when Martian drones spin their blades, they encounter dust grains from the constant storms and dust devils on the Red Planet's surface.
"As the blades impact the grains, charge is transferred, building up on the blades and creating an electric field," NASA said in the statement. "As charge builds to high levels, the atmosphere starts to conduct electricity, a process known as 'atmospheric breakdown.' [The process is] creating a population of electrons that form an enhanced electric current that acts to dissipate or offset the charge build-up on the rotorcraft."
NASA's Ingenuity Mars helicopter acquired this image of its own shadow with its navigation camera on Dec. 15, 2021, during the robot’s 18th Red Planet flight. (Image credit: NASA/JPL-Caltech)
A study based on this research was published March 10, 2021 in the Planetary Science Journal, and NASA chose to highlight the study in a press release this week on Tuesday (Feb. 1).
The study was published before the Perseverance rover and Ingenuity landed on Mars on Feb. 18, 2021; nearly a year later, Ingenuity has made 18 flights and spent more than 30 minutes aloft during these various sorties.
Quelle: SC
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Update: 10.02.2022
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Mars rover Perseverance sets distance record on the Red Planet
The rover topped 800 feet with a self-drive function.
A "selfie" captured by NASA's Perseverance rover, which is searching for signs of ancient life on Mars.(Image credit: NASA/JPL-Caltech/MSSS)
The Perseverance rover's self-driving function is working just great on Mars, according to NASA's Jet Propulsion Laboratory.
The mission, not quite at one Earth year on Mars, has topped a new distance record for Red Planet rovers. On Friday (Feb. 4) Perseverance made the longest drive completed in a single Martian day, or sol, traveling 806.3 feet (245.76 meters), the rover's Twitter feed reported.
Previously that record was held by NASA's Opportunity rover, which traversed 702 feet (214 meters) in a single day in 2015, according to NASA.
"After a few months exploring this area, I'm on the move. Thanks to my self-driving function, I can cover more ground in a day than ever before," the tweetread, adding, "Places to go, rocks to see."
The rover had been squatting in place for several weeks to troubleshoot a rock sample it collected, which temporarily choked the machine's "throat" with Mars rocks. With that problem now cleared, Perseverance is doing some last-minute scouting before attempting a multi-kilometer drive to a nearby delta, recent blog posts indicated.
"The science team has been hard at work preparing for our next phase of science operations, which will take us towards [a] western delta," a Jan. 31 blog post indicated.
Deltas are areas where water flowed, which could provide a rich environment for the rover's ultimate mission to collect samples that could have hosted ancient microbes.
"To prepare, the team has been taking long-distance observations of the delta and layers along Artuby ridge with both the Mastcam-Z and SuperCam instruments," the blog post continued, but it suggested there will be a few pit stops first.
Mission managers must strike a delicate balance between staying in one spot to perform sample collection and moving the rover along to look at other zones in the area.
In the case of the predecessor mission Curiosity, for example, there were periodic debates about how quickly to push the rover to its ultimate destination: Mount Sharp (Aeolis Mons). Curiosity was also finding plenty of signs of water in flatter areas nearby, encouraging periodic pit stops.
Quelle: SC
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Mars helicopter Ingenuity aces 19th flight after historic Red Planet weather delay
A dust storm pushed the liftoff date back by more than a month.
NASA's Mars helicopter Ingenuity captured this image of its own shadow using its navigation camera on Feb. 8, 2022, during the chopper’s 19th Red Planet flight.(Image credit: NASA/JPL-Caltech)
The dust storm couldn't keep NASA's Mars helicopter Ingenuity grounded forever.
The 4-pound (1.8 kilograms) Ingenuity aced a 100-second sortie on Tuesday (Feb. 8), its 19th Red Planet flight overall but its first since Dec. 15.
The flight had originally been targeted for Jan. 5. But on New Year's Day, a big dust storm kicked up near the 28-mile-wide (45 kilometers) Jezero Crater, which Ingenuity and its robotic partner, NASA's Perseverance rover, have been exploring since February 2021.
The Ingenuity team decided to stand down until the dust storm passed, making Ingenuity the first aircraft ever to have a flight delayed by inclement weather on another planet.
Two main factors underlay the decision to delay. First, Ingenuity is solar powered, so lots of dust in the air could affect its ability to recharge its batteries. Second, airborne dust absorbs solar radiation and heats up the surrounding atmosphere, thinning it out slightly. That may not sound like a big deal, but Mars' air is just 1% as dense as that of Earth at sea level, so flying there is tricky even in the best of circumstances.
The delay turned out to be the right call, mission team members said. The dust storm did indeed roll over Jezero Crater, and the effects were observed by NASA's Mars Reconnaissance Orbiter, the weather station aboard Perseverance, and Ingenuity's sensors.
"Most notable was a sharp drop in air density — about a 7% deviation below what was observed pre-dust storm," Jonathan Bapst and Michael Mischna, of Ingenuity's weather and environment team, wrote in an update on Jan. 19.
"This observed decrease would have put density below the lower threshold of safe flight and would have imparted undue risk to the spacecraft," wrote Bapst and Mischna, both of whom are based at NASA's Jet Propulsion Laboratory (JPL) in Southern California. "We also observed the effect of dust in the amount of sunlight absorbed by Ingenuity's solar array, which fell well below normal 'clear sky' levels, a drop of about 18%."
The delay ended up extending into February, apparently out of an abundance of caution, JPL spokesman Andrew Good told Space.com via email last week. "There was a lot of dust in the air after that recent storm," Good said.
Tuesday's flight took Ingenuity out of a rugged patch of Jezero's floor known as South Séítah, over a ridge and onto a plateau, mission team members have said. Ingenuity stayed aloft for 99.98 seconds and covered about 205 feet (62 meters) during the sortie, JPL officials said via Twitter on Tuesday.
Ingenuity is a technology demonstration designed to show that aerial exploration is feasible on Mars. The rotorcraft did just that on five initial flights, which were originally supposed to be the entirety of its mission. But Ingenuity performed so well that NASA approved an extension, during which the chopper is serving as a scout for Perseverance and pushing the boundaries of Red Planet flight.
Quelle: SC
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Update: 18.02.2022
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Celebrate Perseverance rover's 1-year 'Marsiversary' with these events
There are in-person options for some folks and virtual opportunities for anyone with internet access.
The Perseverance rover is about to celebrate one year on Mars, and NASA wants you to be part of the party.
The space agency and mission team members are holding a variety of events around the country to mark the "Marsiversary" of the life-hunting, sample-caching Perseverance and the tiny helicopter Ingenuity, which touched down with the rover on Feb. 18, 2021.
There are exciting in-person events in some places — full-size Perseverance models will be on display in Seattle, San Francisco and New York City, for example — and online experiences that everyone with internet access can enjoy.
For instance, Perseverance Project Manager Jennifer Trosper and Deputy Project Scientist Katie Stack Morgan are giving a talk at 10 p.m. EST on Thursday (Feb. 15; 0300 GMT on Feb. 16) about the science findings from the rover's first year on the Red Planet. You can watch it for free on the YouTube channel of NASA's Jet Propulsion Laboratory in Southern California, which manages Perseverance's mission.
The events run from Thursday through Monday (Feb. 21), and NASA provides a full listing of them here. So take a look, and set some time aside over the next few days to celebrate with the Perseverance and Ingenuity teams and learn more about their pioneering missions!
