Researchers have discovered a surprisingly large amount of water in the upper atmosphere of Mars, where it is rapidly destroyed.
The findings could explain part of the mystery of today’s bone-dry red planet.
“We know that billions of years ago, there was liquid water on the surface of Mars,” says lead author Shane Stone, a graduate student in the University of Arizona Lunar and Planetary Laboratory.
Stone describes himself as a planetary chemist. Once a laboratory chemist who helped to develop polymers used to wrap and deliver therapeutic drugs more efficiently, he now studies the chemistry of planetary atmospheres.
Since 2014, he has worked on NASA’s MAVEN mission, short for Mars Atmosphere and Volatile Evolution. The MAVEN spacecraft began orbiting Mars in 2014 and has recorded the composition of the upper atmosphere of Earth’s planetary neighbor ever since.
“There must have been a thicker atmosphere, so we know that Mars somehow lost the majority of its atmosphere to space,” Stone says. “MAVEN is trying to characterize the processes responsible for this loss, and one portion of that is understanding exactly how Mars lost its water.”
Where’s the Mars water?
As MAVEN orbits Mars, it dips into the planet’s atmosphere every 4 1/2 hours. The onboard NGIMS instrument—short for Neutral Gas and Ion Mass Spectrometer—has been measuring the abundance of charged water molecules called ions in the upper Martian atmosphere, about 100 miles from the planet’s surface. From this information, scientists can infer how much water is present in the atmosphere.
Past observations using MAVEN and the Hubble Space Telescope showed that loss of water from the Martian upper atmosphere varies with the seasons. Compared to Earth, Mars takes a more oval-shaped path around the sun and is closest to it during summer in the Martian southern hemisphere.
Stone and colleagues found that when Mars is nearest the sun, the planet warms, and more water—found on the surface in the form of ice—moves from the surface to the upper atmosphere where it is lost to space. This happens once every Martian year or about every two Earth years. The regional dust storms that occur on Mars every Martian year and the global dust storms that occur across the planet about once every 10 years lead to further heating of the atmosphere and a surge in the upward movement of water.
The processes that make this cyclical movement possible contradict the classical picture of water escape from Mars, showing it is incomplete, Stone says. According to the classical process, ice formed from water is converted to a gas and destroyed by the sun’s rays in the lower atmosphere. This process, however, would play out as a slow, steady trickle, unaffected by the seasons or dust storms, which doesn’t mesh with current observations.
“This is important because we didn’t expect to see any water in the upper atmosphere of Mars at all,” Stone says. “If we compare Mars to Earth, water on Earth is confined close to the surface because of something called the hygropause. It’s just a layer in the atmosphere that’s cold enough to condense (and therefore stop) any water vapor traveling upward.”
The researchers argue that water is moving past what should be Mars’ hygropause, likely too warm to stop the water vapor. Once in the upper atmosphere, water molecules are quickly broken apart by ions—within four hours, they calculate—and the byproducts are then lost to space.
“The loss of its atmosphere and water to space is a major reason Mars is cold and dry compared to warm and wet Earth. This new data from MAVEN reveals one process by which this loss is still occurring today,” Stone says.
Looking back and looking ahead
When the team extrapolated their findings back 1 billion years, they found that this process can account for the loss of a global ocean about 17 inches deep.
“If we took water and spread it evenly over the entire surface of Mars, that ocean of water lost to space due to the new process we describe would be over 17 inches deep,” Stone says. “An additional 6.7 inches would be lost due solely to the effects of global dust storms.”
During global dust storms, 20 times more water can be transported to the upper atmosphere. For example, one global dust storm lasting 45 days releases the same amount of water to space as Mars would lose during a calm Martian year, or 687 Earth days.
And while Stone and his team can’t extrapolate farther back than 1 billion years, he thinks that this process likely didn’t work the same before that, because Mars might have had a stronger hygropause long ago.
“Before the process we describe began to operate, there must have been a significant amount of atmospheric escape to space already,” Stone says. “We still need to nail down the impact of this process and when it began to operate.”
In the future, Stone would like to study the atmosphere of Saturn’s moon Titan.
“Titan has an interesting atmosphere in which organic chemistry plays a significant role,” Stone says. “As a former synthetic organic chemist, I’m eager to investigate these processes.”
The research appears in the journal Science.
Source: University of Arizona