Mars

Life May Have Thrived On Early Mars Until It Drove Climate Change That Caused Its Demise

By Keith Cowing
Press Release
University of Arizona
October 10, 2022
Filed under , , ,
Life May Have Thrived On Early Mars Until It Drove Climate Change That Caused Its Demise
Median evolution of the ice coverage of Noachian Mars under the influence of hydrogenotrophic methanogens for brines freezing at 203 K (top), 252 K (middle), and 273 K (bottom). The orange color-scale represents elevation. The super-imposed white shaded areas correspond to the probability (from 0.5 to 1 by steps of 0.1) of surface ice. See Supplementary Video 1 for an animated version of the 252 K scenario.

If there ever was life on Mars – and that’s a huge “if” – conditions during the planet’s infancy most likely would have supported it, according to a study led by University of Arizona researchers.

Dry and extremely cold, with a tenuous atmosphere, today’s Mars is extremely unlikely to sustain any form of life at the surface. But 4 billion years ago, Earth’s smaller, red neighbor may have been much more hospitable, according to the study, which is published in Nature Astronomy.

Most Mars experts agree that the planet started out with an atmosphere that was much denser than it is today. Rich in carbon dioxide and hydrogen, it would have likely created a temperate climate that allowed water to flow and, possibly, microbial life to thrive, according to Regis Ferrière, a professor in the UArizona Department of Ecology and Evolutionary Biology and one of two senior authors on the paper.

The authors are not arguing that life existed on early Mars, but if it did, Ferrière said, “our study shows that underground, early Mars would very likely have been habitable to methanogenic microbes.”

Such microbes, which make a living by converting chemical energy from their environment and releasing methane as a waste product, are known to exist in extreme habitats on Earth, such as hydrothermal vents along fissures in the ocean floor. There, they support entire ecosystems adapted to crushing water pressures, near-freezing temperatures and total darkness.

The research team tested a hypothetical scenario of an emerging Martian ecosystem by using state-of-the-art models of Mars’ crust, atmosphere and climate, coupled with an ecological model of a community of Earthlike microbes metabolizing carbon dioxide and hydrogen.

On Earth, most hydrogen is tied up in water and not frequently encountered on its own, other than in isolated environments such as hydrothermal vents. Its abundance in the Martian atmosphere, however, could have provided an ample supply of energy for methanogenic microbes about 4 billion years ago, at a time when conditions would have been more conducive to life, the authors suggest. Early Mars would have been very different from what it is today, Ferrière said, trending toward warm and wet rather than cold and dry, thanks to large concentrations of hydrogen and carbon dioxide – both strong greenhouse gases that trap heat in the atmosphere.

“We think Mars may have been a little cooler than Earth at the time, but not nearly as cold as it is now, with average temperatures hovering most likely above the freezing point of water,” he said. “While current Mars has been described as an ice cube covered in dust, we imagine early Mars as a rocky planet with a porous crust, soaked in liquid water that likely formed lakes and rivers, perhaps even seas or oceans.”

That water would have been extremely salty, he added, according to spectroscopic measurements of rocks exposed on the Martian surface.

To simulate the conditions early lifeforms would have encountered on Mars, the researchers applied models that predict the temperatures at the surface and in the crust for a given atmospheric composition. They then combined those data with an ecosystem model that they developed to predict whether biological populations would have been able to survive in their local environment and how they would have affected it over time.

“Once we had produced our model, we put it to work in the Martian crust – figuratively speaking,” said the paper’s first author, Boris Sauterey, a former postdoctoral fellow in Ferrière’s group who is now a postdoctoral fellow at Sorbonne Université in Paris. “This allowed us to evaluate how plausible a Martian underground biosphere would be. And if such a biosphere existed, how it would have modified the chemistry of the Martian crust, and how these processes in the crust would have affected the chemical composition of the atmosphere.”

“Our goal was to make a model of the Martian crust with its mix of rock and salty water, let gases from the atmosphere diffuse into the ground, and see whether methanogens could live with that,” said Ferrière, who holds a joint appointment at Paris Sciences & Lettres University in Paris. “And the answer is, generally speaking, yes, these microbes could have made a living in the planet’s crust.”

The researchers then set out to answer an intriguing question: If life thrived underground, how deep would one have had to go to find it? The Martian atmosphere would have provided the chemical energy that the organisms would have needed to thrive, Sauterey explained – in this case, hydrogen and carbon dioxide.

“The problem is that even on early Mars, it was still very cold on the surface, so microbes would have had to go deeper into the crust to find habitable temperatures,” he said. “The question is how deep does the biology need to go to find the right compromise between temperature and availability of molecules from the atmosphere they needed to grow? We found that the microbial communities in our models would have been happiest in the upper few hundreds of meters.”

By modifying their model to take into account how processes occurring above and below ground influence each other, they were able to predict the climatic feedback of the change in atmospheric composition caused by the biological activity of these microbes. In a surprising twist, the study revealed that while ancient Martian life may have initially prospered, its chemical feedback to the atmosphere would have kicked off a global cooling of the planet, ultimately rendering its surface uninhabitable and driving life deeper and deeper underground, and possibly to extinction.

“According to our results, Mars’ atmosphere would have been completely changed by biological activity very rapidly, within a few tens or hundreds of thousands of years,” Sauterey said. “By removing hydrogen from the atmosphere, microbes would have dramatically cooled down the planet’s climate.”

Early Mars’ surface would soon have become glacial as a consequence of the biological activity. In other words, climate change driven by Martian life might have contributed to making the planet’s surface uninhabitable very early on.

“The problem these microbes would have then faced is that Mars’ atmosphere basically disappeared, completely thinned, so their energy source would have vanished and they would have had to find an alternate source of energy,” Sauterey said. “In addition to that, the temperature would have dropped significantly, and they would have had to go much deeper into the crust. For the moment, it is very difficult to say how long Mars would have remained habitable.”

Future Mars exploration missions may provide answers, but challenges will remain, according to the authors. For example, while they identified Hellas Planitia, an extensive plain carved out by an impact of a large comet or asteroid very early in the history of Mars, as a particularly promising site to scour for evidence of past life, the location’s topography generates some of Mars’ most violent dust storms, which could make the area too risky to be explored by an autonomous rover.

However, once humans begin to explore Mars, such sites could make it back onto the shortlist for future missions to the planet, Sauterey said. For now, the team focuses its research on modern Mars. NASA’s Curiosity rover and the European Space Agency’s Mars Express satellite have detected elevated levels of methane in the atmosphere, and while such spikes could result from processes other than microbial activity, they do allow for the intriguing possibility that lifeforms such as methanogens may have survived in isolated pockets on Mars, deep underground – oases of alien life in an otherwise hostile world.

Early Mars habitability and global cooling by H2-based methanogens, Nature Astronomy

Researcher contact:
Régis Ferrière
Department of Ecology and Evolutionary Biology
520-626-4741
[email protected]

Media contact:
Daniel Stolte
University Communications
520-626-4402
[email protected]

Astrobiology

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