Second cycle of martian seasons completing for Curiosity rover

The repetition helps distinguish seasonal effects from sporadic events.
By and | Published: May 12, 2016 | Last updated on May 18, 2023
Seasonal cycles at Gale Crater
By monitoring weather throughout two martian years since landing in Gale Crater in 2012, NASA’s Curiosity Mars rover has documented seasonal patterns such as shown in these graphs of temperature, water-vapor content, and air pressure.
NASA’s Curiosity Mars rover completed its second martian year since landing inside Gale Crater nearly four Earth years ago, recording environmental patterns through two full cycles of martian seasons.

The repetition helps distinguish seasonal effects from sporadic events. For example, a large spike in methane in the local atmosphere during the first southern-hemisphere autumn in Gale Crater was not repeated the second autumn. It was an episodic release, still unexplained. However, the rover’s measurements do suggest that much subtler changes in the background methane concentration — amounts much less than during the spike — may follow a seasonal pattern. Measurements of temperature, pressure, ultraviolet light reaching the surface, and the scant water vapor in the air at Gale Crater show strong, repeated seasonal changes.

Monitoring the modern atmosphere, weather, and climate fulfills a Curiosity mission goal supplementing the better-known investigations of conditions billions of years ago. Back then, Gale Crater had lakes and groundwater that could have been good habitats for microbes, if Mars has ever had any. Today, though dry and much less hospitable, environmental factors are still dynamic.

Curiosity’s Rover Environmental Monitoring Station (REMS), supplied by Spain’s Centro de Astrobiología, has measured air temperatures from 60.5° F (15.9° C) on a summer afternoon to –148° F (–100 C) on a winter night.

“Curiosity’s weather station has made measurements nearly every hour of every day, more than 34 million so far,” said Ashwin Vasavada of NASA’s Jet Propulsion Laboratory (JPL) in Pasadena, California. “The duration is important because it’s the second time through the seasons that lets us see repeated patterns.”

Each martian year — the time it takes the Red Planet to orbit the sun once — lasts 687 Earth days. Curiosity landed on August 5, 2012 (Pacific Time). It begins its third martian year on May 11, 2016, during the mission’s 1,337th martian day, or “sol,” since landing. Each martian sol lasts about 39.6 minutes longer than an Earth day, and a martian year lasts 668.6 sols.

The similar tilts of Earth and Mars give both planets a yearly rhythm of seasons. But some differences are great, such as in comparisons between day and night temperatures. Even during the time of the martian year when temperatures at Gale Crater rise above freezing during the day, they plummet overnight to below minus 130° F (–90° C) due to the thin atmosphere. Also, the more elliptical orbit of Mars, compared to Earth, exaggerates the southern-hemisphere seasons, making them dominant even at Gale Crater’s near-equatorial location.

“Mars is much drier than our planet, and in particular Gale Crater, near the equator, is a very dry place on Mars,” said Germán Martínez, a Curiosity science-team collaborator from Spain at the University of Michigan, Ann Arbor. “The water vapor content is a thousand to 10 thousand times less than on Earth.”

Relative humidity is a function of both temperature and water-vapor content. During winter nights, Curiosity has measured relative humidity of up to 70 percent, high enough to prompt researchers to check for frost forming on the ground. Other Mars landers have detected frost, but Curiosity has not.

Curiosity’s air-pressure measurements confirm a strong seasonal trend previously seen by other missions. “There are large changes due to the capture and release of carbon dioxide by the seasonal polar caps,” Martínez said. Most of the martian atmosphere is carbon dioxide. During each pole’s winter, millions of tons of this gas freeze solid, only to be released again in spring, prompting very un-Earthlike seasonal variations of about 25 percent in atmospheric pressure.

Other seasonal patterns measured by Curiosity and repeated in the rover’s second martian year are that the local atmosphere is clear in winter, dustier in spring and summer, and windy in autumn. Visibility in Gale Crater is as low as 20 miles (30 kilometers) in summer and as high as 80 miles (130km) in winter.

For tracking changes in the concentration of methane in the air above Gale Crater, researchers use the tunable laser spectrometer in Curiosity’s Sample Analysis at Mars (SAM) suite of instruments. These measurements are made less often than REMS measurements, though frequently enough to tease out seasonal patterns. For most of the two martian years, the rover has measured methane concentrations between 0.3 and 0.8 parts per billion. For several weeks during the first autumn, the level spiked, reaching 7 parts per billion. The mission checked carefully for a repeat of that spike during the second autumn, but concentrations stayed at lower background levels.

“Doing a second year told us right away that the spike was not a seasonal effect,” said Chris Webster from JPL. “It’s apparently an episodic event that we may or may not ever see again.”

However, the mission is continuing to monitor a possible seasonal pattern in the background methane concentration. The background level is far less than the spike level, but it appears to be even lower in autumn than in other seasons. If this pattern is confirmed, it may be related to the pressure pattern measured by REMS or to seasonal change in ultraviolet radiation, which is measured by REMS in concert with the rover’s Mast Camera.

“This shows not only the importance of long-term monitoring, but also the importance of combining more than one type of measurement from a single platform,” Webster said.

While continuing to study the modern local environment, Curiosity is investigating geological layers of lower Mount Sharp, inside Gale Crater, to increase understanding of ancient changes in environmental conditions