Signs of Mars life may be too elusive for rovers to detect (Image Credit: Space.com)
The robots currently exploring Mars may not be capable of detecting potential traces of life on the Red Planet, a new study finds.
The twin Viking orbiters NASA sent to Mars nearly a half-century ago discovered that the Red Planet possessed liquid water on its surface early in its history, about three billion to four billion years ago. Later missions have supported these findings, suggesting that organisms might once have lived there, and might still, since life is found virtually wherever there is water on Earth.
However, NASA’s two Viking landers detected no unambiguous native organic chemicals within Martian soil, even at levels of parts per billion. Even the most recent, highly advanced instruments of NASA’s later Curiosity and Perseverance rovers have found just traces of simple organic molecules in ancient Martian lakebeds and river deltas. And these compounds are not solid evidence of life; they could have been produced by geological processes, scientists have stressed.
Related: Life on Mars: Exploration and evidence
It remains uncertain if the hunt for past or present life on Mars has fallen short because the Red Planet has always been barren or because the probes sent there are not sensitive enough to detect any life onsite. To help solve this mystery, scientists tested instruments that are currently or may be sent to Mars alongside highly sensitive lab equipment.
The researchers analyzed samples from Red Stone, the remains of a river delta in the Atacama Desert of Chile, one of the oldest and driest deserts on Earth. These deposits, which formed under highly arid conditions about 100 million to 160 million years ago, strongly resemble Mars’ Jezero Crater, which Perseverance is currently investigating.
Red Stone regularly experiences fogs that supply water for microbes that live at the site. The state-of-the-art lab techniques the scientists used found a mixture of biochemicals from both extinct and living microorganisms there. About half of the DNA sequences detected at Red Stone came from the “dark microbiome” — that is, microbes that researchers have not yet properly described.
However, the testbed versions of instruments currently on or planned for Mars — including one 10 times more sensitive than one on Curiosity — were barely able to detect organic signs of life in Red Stone samples.
“I would have expected that the testbed instruments we tested in order to detect the evidence of life at Red Stone that we knew was there using tools you might find in any microbiology lab would fare better,” study lead author Armando Azua-Bustos, of the Center of Astrobiology in Madrid, told Space.com. “And they didn’t.”
These findings suggest that Mars probes will find it difficult, if not impossible, to detect the kinds of low levels of organic matter expected to be on the Red Planet today if microbial life did indeed exist there billions of years ago.
“We’re still learning how to detect evidence of life on Mars,” Azua-Bustos said. “The current nature of the instruments sent there have their limits. But that’s not because they have been badly designed. We’re still on the learning curve.”
The researchers suggest that future missions to Mars should aim to return samples from the Red Planet to Earth, where they can get tested by the most advanced equipment scientists have in order to help solve the puzzle of whether life ever lived on Mars. NASA and the European Space Agency aim to do just that, by the way, hauling material collected by Perseverance back to Earth as early as 2033.
Future research can analyze the dark microbiome at Red Stone. These microbes are either so different from any known microorganisms that they defy current categories, or they are remnants of the life that used to live in the area when it had water millions of years ago “that have no current relatives now that you can compare them with,” Azua-Bustos said.
All in all, Azua-Bustos noted that much likely remains to be discovered at Red Stone. This new work “is like sampling one street in New York to characterize the whole of New York,” he said.
The scientists detailed their findings (opens in new tab) online Tuesday (Feb. 21) in the journal Nature Communications.
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