NASA/Goddard Space Flight Center
For the first time in the history of space exploration, scientists have measured the seasonal changes in the gases that fill the air directly above the surface of Gale Crater on Mars. As a result, they noticed something baffling: oxygen, the gas many Earth creatures use to breathe, behaves in a way that so far scientists cannot explain through any known chemical processes.
Over the course of three Mars years (or nearly six Earth years) an instrument in the Sample Analysis at Mars (SAM) portable chemistry lab inside the belly of NASA’s Curiosity rover inhaled the air of Gale Crater and analyzed its composition. The results SAM spit out confirmed the makeup of the Martian atmosphere at the surface: 95% by volume of carbon dioxide (CO2), 2.6% molecular nitrogen (N2), 1.9% argon (Ar), 0.16% molecular oxygen (O2), and 0.06% carbon monoxide (CO). They also revealed how the molecules in the Martian air mix and circulate with the changes in air pressure throughout the year. These changes are caused when CO2 gas freezes over the poles in the winter, thereby lowering the air pressure across the planet following redistribution of air to maintain pressure equilibrium. When CO2 evaporates in the spring and summer and mixes across Mars, it raises the air pressure.
Within this environment, scientists found that nitrogen and argon follow a predictable seasonal pattern, waxing and waning in concentration in Gale Crater throughout the year relative to how much CO2 is in the air. They expected oxygen to do the same. But it didn’t. Instead, the amount of the gas in the air rose throughout spring and summer by as much as 30%, and then dropped back to levels predicted by known chemistry in fall. This pattern repeated each spring, though the amount of oxygen added to the atmosphere varied, implying that something was producing it and then taking it away.
“The first time we saw that, it was just mind boggling,” said Sushil Atreya, professor of climate and space sciences at the University of Michigan in Ann Arbor. Atreya is a co-author of a paper on this topic published on November 12 in the Journal of Geophysical Research: Planets.
As soon as scientists discovered the oxygen enigma, Mars experts set to work trying to explain it. They first double- and triple-checked the accuracy of the SAM instrument they used to measure the gases: the Quadrupole Mass Spectrometer. The instrument was fine. They considered the possibility that CO2 or water (H2O) molecules could have released oxygen when they broke apart in the atmosphere, leading to the short-lived rise. But it would take five times more water above Mars to produce the extra oxygen, and CO2 breaks up too slowly to generate it over such a short time. What about the oxygen decrease? Could solar radiation have broken up oxygen molecules into two atoms that blew away into space? No, scientists concluded, since it would take at least 10 years for the oxygen to disappear through this process.
“We’re struggling to explain this,” said Melissa Trainer, a planetary scientist at NASA’s Goddard Space Flight Center in Greenbelt, Maryland who led this research. “The fact that the oxygen behavior isn’t perfectly repeatable every season makes us think that it’s not an issue that has to do with atmospheric dynamics. It has to be some chemical source and sink that we can’t yet account for.”
To scientists who study Mars, the oxygen story is curiously similar to that of methane. Methane is constantly in the air inside Gale Crater in such small quantities (0.00000004% on average) that it’s barely discernable even by the most sensitive instruments on Mars. Still, it’s been measured by SAM’s Tunable Laser Spectrometer. The instrument revealed that while methane rises and falls seasonally, it increases in abundance by about 60% in summer months for inexplicable reasons. (In fact, methane also spikes randomly and dramatically. Scientists are trying to figure out why.)
With the new oxygen findings in hand, Trainer’s team is wondering if chemistry similar to what’s driving methane’s natural seasonal variations may also drive oxygen’s. At least occasionally, the two gases appear to fluctuate in tandem.
“We’re beginning to see this tantalizing correlation between methane and oxygen for a good part of the Mars year,” Atreya said. “I think there’s something to it. I just don’t have the answers yet. Nobody does.”
Oxygen and methane can be produced both biologically (from microbes, for instance) and abiotically (from chemistry related to water and rocks). Scientists are considering all options, although they don’t have any convincing evidence of biological activity on Mars. Curiosity doesn’t have instruments that can definitively say whether the source of the methane or oxygen on Mars is biological or geological. Scientists expect that non-biological explanations are more likely and are working diligently to fully understand them.
Trainer’s team considered Martian soil as a source of the extra springtime oxygen. After all, it’s known to be rich in the element, in the form of compounds such as hydrogen peroxide and perchlorates. One experiment on the Viking landers showed decades ago that heat and humidity could release oxygen from Martian soil. But that experiment took place in conditions quite different from the Martian spring environment, and it doesn’t explain the oxygen drop, among other problems. Other possible explanations also don’t quite add up for now. For example, high-energy radiation of the soil could produce extra O2 in the air, but it would take a million years to accumulate enough oxygen in the soil to account for the boost measured in only one spring, the researchers report in their paper.
“We have not been able to come up with one process yet that produces the amount of oxygen we need, but we think it has to be something in the surface soil that changes seasonally because there aren’t enough available oxygen atoms in the atmosphere to create the behavior we see,” said Timothy McConnochie, assistant research scientist at the University of Maryland in College Park and another co-author of the paper.
The only previous spacecraft with instruments capable of measuring the composition of the Martian air near the ground were NASA’s twin Viking landers, which arrived on the planet in 1976. The Viking experiments covered only a few Martian days, though, so they couldn’t reveal seasonal patterns of the different gases. The new SAM measurements are the first to do so. The SAM team will continue to measure atmospheric gases so scientists can gather more detailed data throughout each season. In the meantime, Trainer and her team hope that other Mars experts will work to solve the oxygen mystery.
“This is the first time where we’re seeing this interesting behavior over multiple years. We don’t totally understand it,” Trainer said. “For me, this is an open call to all the smart people out there who are interested in this: See what you can come up with.”
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Climatologists have rejected this instrument-based data because it doesn’t agree with the more reliable output ‘data” of their models. It’s just a travesty that they can’t get instruments to show what they should show.
Honest question.
What improvements to individual human life on Earth have come from all of space exploration that could not have happened without it?
Robinson Crusoe found the answer https://youtu.be/nzd3Kj5I_wA
For the methane fraction, look no further than microbial contamination on the spacecraft itself. Yes, I know, it was sterilized, yada yada yada. Maybe the spacecraft got exposed on its way to, or on, the launchpad. Perhaps a late repair was needed. What’s that saying? “Life finds a way”. As for the oxygen, it varies a lot at any point, but maybe there’s a coupling/de-coupling agent on rocks which have been exposed for millions of years. What sort of organic slime builds up on those, remembering that organic molecules are found in space.
The photochemistry of UV-activated perchlorates and its bacteriocidal effects are worth noting.
Open Access research article
The SAM instrument on Curiosity (as well as Phoenix lander’s wet chemistry experiment, and the MRO spectroscopic examinations from orbit) has provided evidence of perchlorate abundance in Martian soil.
https://agupubs.onlinelibrary.wiley.com/doi/full/10.1002/jgre.20144
The various Mars Landers probably dropped some small lifeforms on the planet.
The UV-activated Mars surface perchlorate concentrations there is like dropping a microbe culture into a concentrated bleach solution. Even the non-living viruses in the culture deposited there are very likely quickly destroyed.
Published: 06 July 2017
“Perchlorates on Mars enhance the bacteriocidal effects of UV light”
https://www.nature.com/articles/s41598-017-04910-3#Sec6
I bet: a product of photo synthesis. Hence a proof of some form of primitieve life living of CO2.
An interesting planetary science article!
Thanks for posting this CTM. I encourage more science based articles such as this.
How about oxygen levels increase when Mars is closer to Sun, because oxygen is carried with solar wind. The oxygen can come from Sun and it also come from Earth.
Solar system has a lot of oxygen, 40% of Earth surface rock’s mass is oxygen, same with the Moon and Mars and with space rocks. Any oxidized rock which heated very hot will release oxygen. So impactors will release oxygen and rocks hitting the sun will release oxygen. And Earth atmosphere loses oxygen and Earth loss oxygen oxidizes the Moon, in addition the solar wind in general oxidizes the lunar surface:
–While the magnetosphere largely protects whatever’s in it from solar radiation, the strength of the solar winds pushes some particles from Earth’s atmosphere into a section of the magnetotail called the plasma sheet – which the researchers say is the most plausible explanation for how oxygen from Earth ends up embedded in the lunar soil.
“[Earth’s] upper atmosphere consists of oxygen ions that are easily picked up by the solar wind and transported to the Moon,” Terada explained to Rebecca Boyle at The Atlantic.
“Maybe some portion is implanted on the Moon, and some portion is lost into interplanetary space.” —
https://www.sciencealert.com/solar-wind-is-blasting-earth-s-oxygen-onto-the-surface-of-the-moon
And in terms of “some portion”- I would say, somewhere around 90% “is lost into interplanetary space.”
So Earth’s atmosphere, and impactors in general including impactors hitting the sun itself and it’s all carried by solar wind, and more carried to Mars distance when Mars is closer to the Sun. Of course also, stuff is constantly oxidizing on Mars surface, or Mars impactors heat strip oxygen and later it re-oxidizes.
And it might also involve Mars going thru periodic comet trail(s) and the “shooting stars” burning up in atmosphere- or dust impacting Mars, itself.
I would tend to think combination of factors, and I suppose if one is looking the major factor, and one might know {I don’t} when Mars has major meteor shows. Or at least eliminate that factor first- as it might be known.
Because the lander is sampling a very small part of the atmosphere very close to the surface, my money will be on seasonal absorption/desorption into and out of the crustal material that is close to the sampler. Keep in mind as well that the percentages reported are, in my opinion, unlikely to represent the fully mixed atmosphere.
Any ideas on how to terraform Mars and make it more Earth-like? Increase the oxygen and nitrogen, reduce the CO2, and start to transform the soil?
Very few Earth plants exist without obtaining water-soluble nutrients from wet soil or from surrounding waters. To the best of our current knowledge, there are no such sources of plant nutrient sources available on the surface of Mars.
Epiphytic plants (aka “air plants” because they seemingly survive on thin air) such as certain lichens, mosses, and algae might be a possibility for early introduction, but would most certainly have to be genetically modified to survive the intense UV radiation and low absolute pressure at the surface of Mars.
There is the possibility of liquid water under the surface of Mars, but this is not conducive to photosynthesis that is the basis of all plant life as we know it. Even achlorophyllous (aka holoparasitic) plants, having no chlorophylls themselves, rely on plant hosts that live via photosynthesis.
The cyclic appearance of methane and oxygen does not prove that life exists on Mars, but it is a more promising case than if Mars were as sterile as the Moon. It means that the confirmation of life, if it comes, will be less of a surprise than previously thought.
Life appeared on Earth almost as soon as the planet cooled enough to allow it. That suggests that the appearance of life even in harsh conditions is not an unlikely event. I expect it to be discovered somewhere in the Solar System and maybe on Mars.
Earth has life a mile under rocky surface, Mars would warm enough a mile under it’s surface.
And Mars could large lakes/very small liquid oceans under 1 mile of Mars surface.
Many think Earth life might have begun due to volcanic heat, and many think there could life elsewhere in solar system depending on volcanic heat.
We don’t know much about the life on Earth a mile under the surface, it seems if want to know more about “alien life” in our solar system, it starts by getting more knowledge about “alien life” a mile under Earth surface.
But if you not interested in microbial life, but instead interested in “higher life forms”, it seems the moons of the gas giants, like Jupiter, would best choice. Mainly due large oceans and large amount of volcanic heat.
“Plasma technology could hold the key to creating a sustainable oxygen supply on Mars, a new study has found. It suggests that Mars, with its 96 per cent carbon dioxide atmosphere, has nearly ideal
conditions for creating oxygen from CO2 through a process known as decomposition.”
What about oxygen Plasma on Mars + Solar Winds:
https://www.google.com/search?client=ms-android-huawei&sxsrf=ACYBGNTHLAeVKb_lut6Fk_rOsA2wNJVgHw%3A1574615841868&ei=IbvaXafZNInQrgTG9LSwAw&q=Mars+oxygen+plasma&oq=Mars+oxygen+plasma&gs_l=mobile-gws-wiz-serp.
https://www.google.com/search?q=solar+wind+plasma&oq=solar+wind+&aqs=chrome.