Water flowed on Mars as recently as 2 billion to 2.5 billion years ago – more recently than previously thought, a new study reveals.
Researchers at California Institute of Technology (Caltech) used NASA’s Mars Reconnaissance Orbiter to determine that liquid water on the Martian surface left salt minerals as recently as 2 billion years ago.
The chloride salt deposits were left behind as icy meltwater flowing across the Martian landscape evaporated.
The salt minerals were first discovered 14 years ago by NASA’s Mars Odyssey orbiter, which launched in 2001.
MRO, which has higher-resolution instruments than Odyssey, launched in 2005 and has been studying the salts, among many other features of Mars, ever since.
Until now, it’s been thought that Mars’ liquid surface water evaporated about 3 billion years ago, but the new results put this forward by up to a billion years.
NASA’s Mars Reconnaissance Orbiter used its Context Camera to capture this image of Bosporos Planum, a location on Mars. The white specks are salt deposits found within a dry channel. The largest impact crater in the scene is nearly 1 mile (1.5km) across
IS THERE WATER ON MARS TODAY?
Today, Martian water ice is locked away underground throughout the planet’s mid-latitudes.
On Earth, usually the ice is just water ice – i.e. frozen H2O. But on Mars, it’s actually water ice and CO2 ice mixed with each other.
On Mars, it’s just so cold that it gets frozen, so you actually have those mixed together both at the poles and underneath the surface as well.
There is also a very small amount of water vapour in the Martian atmosphere.
The new study was conducted by Ellen Leask and Bethany Ehlmann, two researchers working at Caltech’s Division of Geological and Planetary Sciences.
The team looked at imagery of deposits of sodium chloride (table salt) captured by the Mars Reconnaissance Orbiter (MRO).
Using both cameras to create digital elevation maps, Leask and Ehlmann found that many of the salts were in depressions once home to shallow ponds on gently sloping volcanic plains.
The scientists also found winding, dry channels nearby – former streams that once fed surface runoff (from the occasional melting of ice or permafrost) into these ponds.
Crater counting and evidence of salts on top of volcanic terrain allowed them to date the deposits. Generally, the fewer craters a terrain has, the younger it is. By counting the number of craters on an area of the surface, scientists can estimate its age.
Chloride salt deposits on Mars are ‘intriguing’, the duo say, because they dissolve very readily and so record the last stage of liquid water present at Mars’ surface.
‘Salt is incredibly soluble, so any moisture at all would dissolve it,’ said Leask, now a postdoctoral scholar at Johns Hopkins University’s Applied Physics Laboratory.
‘As such, these deposits must have formed during the evaporation of the last large-scale water on the planet. ‘
Mars once rippled with rivers and ponds billions of years ago, providing a potential habitat for microbial life.
NASA’s aging Mars Reconnaissance Orbiter (depicted here) is the most data-productive spacecraft circling the Red Planet
Technicians perform checks on the Mars Reconnaissance Orbiter (MRO) prior to its departure on July 20, 2005
WATER ON MARS UNLIKELY: LAKE DETECTED IS LIKELY JUST A DUSTY MIRAGE
Hope of finding liquid water on Mars has dried up, according to scientists who say what was thought to be a vast lake under the south pole is likely nothing more than a dusty mirage.
In 2018 scientists thought they were looking at liquid water on Mars, after seeing bright radar reflections under the polar ice cap, but a new study disputes that.
Re-examining the reflections in the radar images, planetary scientists from the University of Texas determined they were actually showing volcanic rock.
Read more: Lake detected is likely just a dusty mirage, study says
But as the planet’s atmosphere thinned over time, that water evaporated, leaving the frozen desert world of the present day.
Hundreds of deposits of sodium chloride stretching tens to hundreds of square kilometers in area were discovered by NASA’s 2001 Mars Odyssey orbiter starting in 2008.
Not only did they offer evidence that Mars had been much wetter long ago, they also offered a way to determine the last time that water had existed in liquid form on the planet’s surface.
MRO, meanwhile, launched in August 2005 and reached Mars in March 2006. It has accumulated data on Mars over the last 15 years.
Using data from MRO, Leask and Ehlmann conducted a broad study of all of the known salt deposits.
MRO has two cameras suited for this purpose – the Context Camera, with its black-and-white wide-angle lens, helps scientists map the extent of the chlorides.
To zoom in, scientists turn to the High-Resolution Imaging Science Experiment (HiRISE) color camera, allowing them to see details as small as a Mars rover from space.
The experts looked at what types of landforms the salt deposits formed on and how they were deposited across the terrain.
They found they are surprisingly thin – less than 10 feet (3 metres) and occur in topographical lows.
The Martian surface has an estimated temperature of roughly minus 81 degrees Fahrenheit, which would be too cold for water to stay liquid
‘They don’t fill basins like salt deposits in Death Valley,’ said Ehlmann. ‘The closest analogue we can find on Earth are chains of lakes that you get in Antarctica when snow melts seasonally atop permafrost.
‘It cannot penetrate deep into the frozen ground below, so when water evaporates, the salt deposit left behind is thin.’
The Martian salt deposits are often found in shallow depressions, sometimes perched above much larger craters that are devoid of the deposits.
This orientation would seem to indicate the water came from surface runoff during a freeze thaw cycle of ice, with chloride for the salt leached from the top of clay-rich soils, according to the results.
Future missions could analyse the textures of the chlorides to confirm they are indeed the result of evaporation.
The data could also reveal what organic compounds might have been associated with the water when it existed.
Although there’s no liquid water on Mars today, about 4.3 billion years ago the Red Planet had enough water to cover its entire surface in a liquid layer about 450 feet (137 meters) deep, according to NASA.
Fast forward to 3.5 billion years ago, and this water was more scarce – channeled around the planet between crater lakes via rivers, much like on Earth today.
Floods at these lakes created river valleys with high walls of jagged rock on either side, much like Earth’s own impressive modern-day canyons, according to researchers in Texas.
Scientists believe Mars holds large volumes of water but much of it is stored in ice or in brine patches
How important is the presence of liquid water?
It is now widely believed that Mars holds a reasonably large volume of water.
However, the surface of the planet is so cold, this water exists only as ice.
In order for life to exist on a planet, many scientists believe it is essential for the world to possess liquid water.
Ever since technology has enabled mankind to gaze at Mars in detail, humans have been looking for indications that there was water on the red planet.
Did water used to flow on the surface of Mars?
The Mariner 9 mission revealed clues of water erosion in river beds and canyons, as well as evidence of weather fronts and fogs on Mars in 1971.
Later missions from the Viking orbiters, which first launched in 1975, revealed yet more details about how water flowed on the surface and carved valleys.
Several studies investigated the presence of liquid water for decades. In 2000, the first proof of liquid water on Mars was discovered.
It was claimed the gullies seen on the surface of the planet had to have been formed by flowing water.
Scientists cited the debris and mud deposits left behind as evidence for moving water existing at some point in the history of the red planet.
However, the formation of these gullies has been hotly debated throughout the ensuing years.
Proof of ice in geological samples from Mars
Spirit and Opportunity, the twin rovers, found evidence of the presence of water enclosed in rock in 2007, when one of Spirit’s wheels broke and gorged a piece of stone.
Analysis of the silica-rich layer discovered in the scratch suggested it formed in the presence of liquid water.
In 2008, the Phoenix lander was gathering geological samples, and they disappeared after a few days.
Scientists thought these were pieces of ice. This assessment was confirmed when the lander later detected water vapour in a sample.
In 2012, Curiosity was meandering over an ancient martian seabed when it examined a number of rocks that were exposed to liquid water billions of years ago.
In 2012, Curiosity (pictured) was meandering over an ancient martian seabed when it examined a number of rocks that were exposed to liquid water billions of years ago
Recurring slope lineae and debate causes it
Features known as recurring slope lineae (RSL) were first identified in 2011.
These dark streaks populate the areas of Mars with a sharp incline.
Researchers speculated that these may have been caused by the intermittent flow of liquid water down steep banks on the planet.
In June 2013, Curiosity found powerful evidence that water good enough to drink once flowed on Mars. In September of the same year, the first scoop of soil analysed by Curiosity revealed that fine materials on the surface of the planet contain two per cent water by weight.
In 2015, Nasa claimed to have discovered the first evidence of liquid water on Mars in the present day.
The space agency said that its Mars Reconnaissance Orbiter (MRO) provided the strongest evidence yet that liquid water flows intermittently on present-day Mars.
In 2017, Nasa issued another statement rebuking its initial findings.
Features known as recurring slope lineae (RSL) were first identified in 2011 (pictured). These dark streaks populate the areas of Mars with a sharp incline. Researchers speculated that these may have been caused by the intermittent flow of liquid water
It said the dark features that run down steep inclines on the red planet were actually granular flows, where grains of sand and dust slip downhill to make dark streaks, rather than the ground being darkened by seeping water.
Images from the MRO revealed the streaks only exist on slopes steep enough for dry grains to descend the way they do on faces of active dunes.
Also in 2017, scientists provided the best estimates for water on Mars, claiming it once had more liquid H2O than the Arctic Ocean – and the planet kept these oceans for more than 1.5 billion years.
The findings suggest there was ample time and water for life on Mars to thrive, but over the last 3.7 billion years the red planet has lost 87 per cent of its water – leaving the surface barren and dry.
A subterranean lake
In a study published in the journal Science, ESO researchers have now discovered the first concrete evidence for liquid water on Mars.
Using radar imagery from the Mars Express probe, the ESO team have found a 12-mile long underground lake filled with liquid water.