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The Perseverance rover on Mars
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New Perseverance rover research provides more signs of possible organic molecules on Mars

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  • Space
  • Graduate and professional students
  • Kenneth P. Dietrich 麻豆传媒 of Arts and Sciences

Little green men it isn鈥檛 鈥 but a new study co-led by a Pitt PhD candidate shows the potential for a variety of carbon-based molecules in a crater on Mars. The research isn鈥檛 proof of life on Mars, nor is it even proof of organic matter. But it does offer new lines of evidence suggesting molecules sometimes associated with life may be found on the red planet.

鈥淲e saw signals that could be associated with organic material, and so we鈥檙e pretty excited about those findings and the possibilities those could have,鈥 said , a Pitt chemistry PhD candidate and co-lead author of the study. 鈥淚 wouldn鈥檛 say that it鈥檚 at high concentrations, but it鈥檚 there wherever we鈥檝e looked. That was quite surprising.鈥

The rover began its Martian journey in February 2021, and since then has been exploring Jezero Crater, which scientists believe was once full of water and thus a prime location to search for signs of past life on the planet.

It鈥檚 aided in its search for life by SHERLOC (short for Scanning Habitable Environments with Raman and Luminescence for Organics), an instrument developed by a team including Roppel鈥檚 advisor, , a distinguished professor of chemistry in the Kenneth P. Dietrich 麻豆传媒 of Arts and Sciences. SHERLOC is especially sensitive in the range of signals produced by organic molecules 鈥 those that contain the element carbon and that, on Earth, are often associated with life.

In the new study, the team found signals similar to what scientists expect from a class of ring-shaped molecules called aromatic hydrocarbons, which were especially common in areas that appear to have a wetter past. While this isn鈥檛 the first paper to show signs of organic matter in the area 鈥 Roppel and Asher were both co-authors on the first, too, 鈥 in the new work, they searched over a wider area and found a wider range of signals.

The team, including researchers from more than two dozen institutions and co-led by Sunanda Sharma of NASA鈥檚 Jet Propulsion Laboratory, on July 12.

A closer look

Key to the new results was the use of UV fluorescence as well as Raman spectroscopy, where researchers shine ultraviolet lasers at a material of interest and measure the color of light that bounces back: depending on its molecular structure, each chemical scatters light differently. Asher and his team have been on the leading edge of this technique since the 1980s, using it to detect the presence of everything from explosives to proteins that may signal diseases like Alzheimer鈥檚.

Compared to the tools available on past missions to Mars, this kind of measurement allows researchers to get a more fine-grained view of where potential organic molecules are and which Martian minerals they鈥檙e associated with. While researchers have a long history of matching what they find from Raman spectroscopy with different materials on Earth, Mars has its own history. They鈥檙e starting from scratch, so each new point of data expands the kinds of associations that can be made and ideas that can be tested.

All the while, researchers at Pitt work with a version of SHERLOC housed in Asher鈥檚 lab, testing materials to see if they can recreate the kinds of signals they鈥檙e seeing on the red planet.听

鈥淲e鈥檙e still working with the same elements as we have on Earth, but the context of what happened geologically is completely different,鈥 said Asher. 鈥淎s we increase our experience and our knowledge base, we鈥檙e able to come to richer and more incisive conclusions.鈥

Eliminate the impossible

There鈥檚 no shortage of alternate possibilities that need to be ruled out in the search for alien life. Some nonorganic molecules can look the same as organic ones to a spectrometer. Plus, there are many ways to form organic molecules 鈥 not all of which require the presence of life 鈥 and many different processes could cause the patterns of molecules found across the mosaic of minerals in Jezero Crater.

For instance, those pattens could be the result of chemistry from the crater鈥檚 waterlogged history, or it may be that certain kinds of minerals trap and preserve organic molecules better than others across billions of years of being bombarded with radiation. Then there鈥檚 the ever-present Martian dust.

鈥淚f you like complex puzzles, this is a nice one,鈥 said Asher.

There鈥檒l be more to find as Perseverance proceeds on its journey. Already, it鈥檚 rolled off the crater floor and up into a former river delta, and the research team continues to interpret and prepare more of the rover鈥檚 findings for publication. SHERLOC has plenty more to teach us about the Martian landscape over the next few years 鈥 and the wait for certainty about the presence of organic molecules will likely be longer.

鈥淲e actually have the ability to store these samples onboard the rover and eventually bring them back to Earth,鈥 said Roppel. 鈥淲e鈥檙e hoping to get a lot of the samples mentioned in this manuscript back to Earth as part of the Mars Sample Return mission in the early 2030s. So that鈥檚 pretty exciting.鈥

Photo credit: NASA/JPL-Caltech