Home NEWS NASA Rover Captures Mars From Dawn to Dusk First Time

NASA Rover Captures Mars From Dawn to Dusk First Time

NASA Rover Captures Mars From Dawn to Dusk First Time

NASA Rover Captures Mars From Dawn to Dusk First Time
Curiosity Mars rover captured this 360-degree panorama while parked below Gediz Vallis Ridge (the hill-like slope at right). After three attempts over the course of three years, the rover finally reached the ridge on its fourth try on August 14, 2023. Pic: NASA

When NASA’s Curiosity Mars rover isn’t on the move, it works pretty well as a sundial, as seen in two black-and-white videos recorded on November 8, the 4,002nd Martian day, or sol, of the mission. The rover captured its own shadow shifting across the surface of Mars using its black-and-white Hazard-Avoidance Cameras, or Hazcams.

Instructions to record the videos were part of the last set of commands beamed up to Curiosity just before the start of Mars solar conjunctiona period when the Sun is between Earth and Mars. Because plasma from the Sun can interfere with radio communications, missions hold off on sending commands to Mars spacecraft for several weeks during this time. (The missions weren’t totally out of contact: They still radioed back regular health check-ins throughout conjunction.)

Rover drivers normally rely on Curiosity’s Hazcams to spot rocks, slopes, and other hazards that may be risky to traverse. But because the rover’s other activities were intentionally scaled back just before conjunction, the team decided to use the Hazcams to record 12 hours of snapshots for the first time, hoping to capture clouds or dust devils that could reveal more about the Red Planet’s weather.

When the images came down to Earth after conjunction, scientists didn’t see any weather of note, but the pair of 25-frame videos they put together do capture the passage of time. Extending from 5:30 a.m. to 5:30 p.m. local time, the videos show Curiosity’s silhouette shifting as the day moves from morning to afternoon to evening.

The first video, featuring images from the front Hazcam, looks southeast along Gediz Vallis, a valley found on Mount Sharp. Curiosity has been ascending the base of the 3-mile-tall (5-kilometer-tall) mountain, which sits in Gale Crater, since 2014.

As the sky brightens during sunrise, the shadow of the rover’s 7-foot (2-meter) robotic arm moves to the left, and Curiosity’s front wheels emerge from the darkness on either side of the frame. Also becoming visible on the left is a circular calibration target mounted on the shoulder of the robotic arm. Engineers use the target to test the accuracy of the Alpha Particle X-ray Spectrometeran instrument that detects chemical elements on the Martian surface.

In the middle of the day, the front Hazcam’s autoexposure algorithm settles on exposure times of around one-third of a second. By nightfall, that exposure time grows to more than a minute, causing the typical sensor noise known as “hot pixels” that appears as white snow across the final image.

These images have been re-projected to correct the wide-angle lenses of the Hazcams. The speckled appearance of the images, especially prominent in the rear-camera video, is due to 11 years of Martian dust settling on the lenses.

The Rover Curiosity

Four thousand Martian days after setting its wheels in Gale Crater on Aug. 5, 2012, NASA’s Curiosity rover remains busy conducting exciting science. The rover recently drilled its 39th sample and then dropped the pulverized rock into its belly for detailed analysis.

To study whether ancient Mars had the conditions to support microbial life, the rover has been gradually ascending the base of 3-mile-tall (5-kilometre-tall) Mount Sharp, whose layers formed in different periods of Martian history and offer a record of how the planet’s climate changed over time.

he latest sample was collected from a target nicknamed “Sequoia” (all of the mission’s current science targets are named after locations in California’s Sierra Nevada). Scientists hope the sample will reveal more about how the climate and habitability of Mars evolved as this region became enriched in sulfates –minerals that likely formed in salty water that was evaporating as Mars first began drying up billions of years ago. Eventually, Mars’ liquid water disappeared for good.

“The types of sulfate and carbonate minerals that Curiosity’s instruments have identified in the last year help us understand what Mars was like so long ago. We’ve been anticipating these results for decades, and now Sequoia will tell us even more,” said Ashwin Vasavada, Curiosity’s project scientist at NASA’s Jet Propulsion Laboratory in Southern California, which leads the mission.

Deciphering the clues to Mars’ ancient climate requires detective work. In a recent paper published in the Journal of Geophysical Research: Planetsteam members used data from Curiosity’s Chemistry and Mineralogy (Path) instrument to discover a magnesium sulfate mineral called starkeyite, which is associated with especially dry climates like Mars’ modern climate.

The team believes that after sulfate minerals first formed in salty water that was evaporating billions of years ago, these minerals transformed into starkeyite as the climate continued drying to its present state. Findings like this refine scientists’ understanding of how the Mars of today came to be.

Time-Tested Rover

Despite having driven almost 20 miles (32 kilometres) through a punishingly cold environment bathed in dust and radiation since 2012, Curiosity remains strong. Engineers are currently working to resolve an issue with one of the rover’s main “eyes” – the 34 mm focal length left camera of the Mast Camera, or Mastcam, instrument. In addition to providing colour images of the rover’s surroundings, each of Mastcam’s two cameras helps scientists determine from afar the composition of rocks by the wavelengths of light, or spectra, they reflect in different colours.

To do that, Mastcam relies on filters arranged on a wheel that rotates under each camera’s lens. Since Sept. 19, the left camera’s filter wheel has been stuck between filter positionsthe effects of which can be seen in the mission’s raw, or unprocessed, images. The mission continues to gradually nudge the filter wheel back toward its standard setting.

If unable to nudge it back all the way, the mission would rely on the higher resolution 100 mm focal length right Mastcam as the primary color-imaging system. As a result, how the team scouts for science targets and rover routes would be affected: The right camera needs to take nine times more images than the left to cover the same area. The teams also would have a degraded ability to observe the detailed colour spectra of rocks from afar.

Along with efforts to nudge the filter back, mission engineers continue to closely monitor the performance of the rover’s nuclear power source and expect it will provide enough energy to operate for many more years. They have also found ways to overcome challenges from wear on the rover’s drill system and robotic arm joints. Software updates have fixed bugs and added new capabilities to Curiosity, too, making long drives easier for the rover and reducing wheel wear that comes from steering (an earlier addition of a traction-control algorithm also helps reduce wheel wear from driving over sharp rocks).

Meanwhile, the team is preparing for a break of several weeks in November. Mars is about to disappear behind the Sun, a phenomenon known as solar conjunction. Plasma from the Sun can interact with radio waves, potentially interfering with commands during this time. Engineers are leaving Curiosity with a to-do list from Nov. 6 to 28, after which period communications can safely resume.

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