Curiosity rover’s discovery of manganese oxide points to a more Earth-like planet
27 June 2016
WASHINGTON, DC — The discovery of manganese oxides in Martian rocks might tell us that the Red Planet was once more Earth-like than previously believed. A new paper in Geophysical Research Letters, a journal of the American Geophysical Union, reveals NASA’s Curiosity rover observed high levels of manganese oxides in Martian rocks, which could indicate higher levels of atmospheric oxygen once existed on our neighboring planet. This hint of more oxygen in Mars’ early atmosphere adds to other Curiosity findings—such as evidence of ancient lakes—revealing how Earth-like our neighboring planet once was.
“The only ways on Earth that we know how to make these manganese materials involve atmospheric oxygen or microbes,” said Nina Lanza, a planetary scientist at Los Alamos National Laboratory and lead author of the new study. “Now we’re seeing manganese-oxides on Mars and wondering how the heck these could have formed.”
Lanza uses the Los Alamos-developed ChemCam instrument that sits atop Curiosity to “zap” rocks on Mars and analyze their chemical make-up. This work stems from Los Alamos National Laboratory’s experience building and operating more than 500 spacecraft instruments for national defense, giving the Laboratory the expertise needed to develop discovery-driven instruments like ChemCam. In less than four years since landing on Mars, ChemCam has analyzed roughly 1,500 rock and soil samples.
The Curiosity rover examines the Kimberley formation in Gale crater, Mars. In front of the rover are two holes from the rover’s sample-collection drill and several dark-toned features that have been cleared of dust (see inset images). These flat features are erosion-resistant fracture fills that are composed of manganese oxides, which require abundant liquid water and strongly oxidizing conditions to form. The discovery of these materials suggests that the Martian atmosphere might once have contained higher abundances of free oxygen than in the present day.
Credit: MSSS/JPL/NASA.
Microbes seem a far-fetched explanation for the manganese oxides at this point, Lanza said, but the idea that the Martian atmosphere contained more oxygen in the past than it does now seems possible.
“These high-manganese materials can’t form without lots of liquid water and strongly oxidizing conditions,” Lanza said. “Here on Earth, we had lots of water but no widespread deposits of manganese oxides until after the oxygen levels in our atmosphere rose due to photosynthesizing microbes.”
In Earth’s geological record, the appearance of high concentrations of manganese is an important marker of a major shift in our atmosphere’s composition, from relatively low oxygen abundances to the oxygen-rich atmosphere we see today. The presence of the same types of materials on Mars suggests something similar happened there. If that’s the case, how was that oxygen-rich environment formed?
“One potential way that oxygen could have gotten into the Martian atmosphere is from the breakdown of water when Mars was losing its magnetic field,” Lanza said. “It’s thought that at this time in Mars’ history, water was much more abundant.” Yet without a protective magnetic field to shield the surface from ionizing radiation, that radiation started splitting water molecules into hydrogen and oxygen. Because of Mars’ relatively low gravity, it wasn’t able to hold onto the very light hydrogen atoms, but the heavier oxygen atoms remained behind. Much of this oxygen went into the rocks, leading to the rusty red dust that covers the surface today. While Mars’ famous red iron oxides require only a mildly oxidizing environment to form, manganese oxides require a strongly oxidizing environment. These results suggest past conditions were far more oxygen-rich than previously thought.
“It’s hard to confirm whether this scenario for Martian atmospheric oxygen actually occurred,” Lanza added. “But it’s important to note that this idea represents a departure in our understanding for how planetary atmospheres might become oxygenated.” So far, abundant atmospheric oxygen has been treated as a so-called biosignature, or a sign of existing life.
The next step in this work is for scientists to better understand the signatures of non-biogenic versus biogenic manganese, which is directly produced by microbes. If it’s possible to distinguish between manganese oxides produced by life and those produced in a non-biological setting, that knowledge can be directly applied to Martian manganese observations to better understand their origin.
The high-manganese materials were found in mineral-filled cracks in sandstones in the Kimberley region of Gale crater, which the Curiosity rover has been exploring for the last four years. But that’s not the only place on Mars that abundant manganese has been found. The Opportunity rover, which has been exploring Mars since 2004, also recently discovered high-manganese deposits in its landing site thousands of miles from Curiosity, which supports the idea that the conditions needed to form these materials were present well beyond Gale crater.
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“Oxidation of manganese in an ancient aquifer, Kimberley formation, Gale crater, Mars”
Authors:
Nina L. Lanza, Roger C. Wiens, Samuel M. Clegg, Ann M. Ollila: Los Alamos National Laboratory, Los Alamos, New Mexico, U.S.A.;
Raymond E. Arvidson: Washington University in Saint Louis, St. Louis, Missouri, U.S.A.;
Benton C. Clark: Space Science Institute, Boulder, Colorado, U.S.A.;
Woodward W. Fischer, John P. Grotzinger: California Institute of Technology, Pasadena, California, U.S.A.;
Ralf Gellert, John L. Campbell, Scott VanBommel: University of Guelph, Guelph, Ontario, Canada;
Joel A. Hurowitz, Scott M. McLennan: Stony Brook University, Stony Brook, New York, U.S.A.;
Richard V. Morris, Douglas W. Ming: NASA Johnson Space Center, Houston, Texas, U.S.A.;
Melissa S. Rice: Western Washington University, Bellingham, Washington, U.S.A.;
James F. Bell III, Craig Hardgrove: Arizona State University, Tempe, Arizona, U.S.A.;
Jeffrey A. Berger: University of Western Ontario, London, Ontario, Canada;
Diana L. Blaney, Fred Calef III: Jet Propulsion Laboratory, Pasadena, California, U.S.A.;
Nathan T. Bridges, Jeffrey R. Johnson: Applied Physics Laboratory, Johns Hopkins University, Laurel, Maryland, U.S.A.;
Agnes Cousin, Olivier Forni, Jeremie Lasue, Sylvestre Maurice, Susanne Schröder: Institut de Recherche en Astrophysique et Planétologie (IRAP), Toulouse, France;
Kenneth S. Edgett, Michael C. Malin: Malin Space Science Systems, San Diego, California, U.S.A.;
Cécile Fabre: Université de Lorraine, Nancy, France;
Martin R. Fisk: Oregon State University, Corvallis, Oregon, U.S.A.;
Jens Frydenvang: Niels Bohr Institute, University of Copenhagen, Copenhagen, Denmark;
Keian R. Hardy: U.S. Naval Academy, Annapolis, Maryland, U.S.A.;
Stéphane Le Mouélic, Nicolas Mangold: LPGNantes, CNRS UMR 6112, Université de Nantes, Nantes, France;
Javier Martìn-Torres: Instituto Andaluz de Ciencias de la Tierra (CSIC-UGR), Granada, Spain, and Luleå University of Technology, Kiruna, Sweden;
Marie J. McBride: Purdue University, West Lafayette, Indiana, U.S.A.;
Horton E. Newsom: University of New Mexico, Albuquerque, New Mexico, U.S.A.;
Violaine Sautter: IMPMC, Muséum d’Histoire Naturelle, Paris, France;
Lucy M. Thompson: Univeristy of New Brunswick, New Brunswick, Canada;
Allan H. Treiman: Lunar and Planetary Institute, Houston, Texas, U.S.A.;
David T. Vaniman: Planetary Science Institute, Tucson, Arizona, U.S.A.;
Marìa-Paz Zorzano: Luleå University of Technology, Kiruna, Sweden, and Instituto Nacional de Técnica Aeroespacial, Madrid, Spain.
Contact Information for the Authors:
Nina Lanza: +1 (505) 606-0821, [email protected]
Lauren Lipuma
+1 (202) 777-7396
[email protected]
Los Alamos National Laboratory Contact:
Laura Mullane
+1 (505) 667-6012
[email protected]