- \n
- For years, evidence has grown for an ancient lake<\/strong> once existing in Gale crater on Mars. Now NASA\u2019s Curiosity rover has found yet more clues.<\/li>\n
- The rover found the highest concentrations of iron, manganese and zinc<\/strong> ever seen in one place on Mars. The metal minerals are in well-preserved ripples in rocks.<\/li>\n
- The chemistry and location of the minerals<\/strong> strongly support the presence of a former shallow lake at this location.<\/li>\n<\/ul>\n
Science news, night sky events and beautiful photos,<\/strong> all in one place. Click here to subscribe to our free daily newsletter.<\/p>\n
Ancient lake on Mars<\/h3>\n
Scientists have long thought that there was once a lake, or series of lakes, in Gale crater, where the Curiosity rover has been exploring since 2012. Now, Curiosity has found even more evidence for that ancient lake.<\/p>\n
Researchers led by the Los Alamos National Laboratory said on April 21, 2026, that the rover has discovered the highest concentration of iron, manganese and zinc ever found together on Mars. This deposit of metals is similar to deposits formed by chemical reactions in lakes on Earth. Plus, Curiosity found the metals within ripples in rocks. It seems an ancient shallow lake produced these ripples, and deposited these metals within them. <\/p>\n
Intriguingly, on Earth, deposits like this are almost always inhabited by microbial life. This isn\u2019t proof<\/em> of ancient life on Mars, but the similarities are striking.<\/p>\n
The researchers published their peer-reviewed findings in the journal JGR Planets<\/em> on April 13, 2026.<\/p>\n
![\"Circular](\"https:\/\/earthsky.org\/upl\/2025\/01\/lake-Gale-crater-Mars-artist-illustration-Kevin-Gill-December-10-2014.jpg\")
View larger. | Artist\u2019s illustration of an ancient lake in Gale crater on Mars. Image via Kevin Gill (CC BY 2.0).<\/figcaption><\/figure>\n Curiosity found a treasure trove of minerals<\/h3>\n
Curiosity found the minerals in late 2022 in a dark section of exposed rock called the Amapari Marker Band. Using its Chemistry & Camera (ChemCam) instrument, the rover detected the iron, manganese and zinc in preserved ripples in the rocks. <\/p>\n
Patrick Gasda, the lead author of the study, explained:<\/p>\n
\n
The metals were found in preserved ripples, which is the clearest evidence we have that a lake was present in Gale crater.<\/p>\n<\/blockquote>\n
![\"3](\"https:\/\/earthsky.org\/upl\/2025\/01\/ripples-Amapari-Marker-Band-outcrop-Curiosity-Mars-January-15-2025.jpg\")
View larger. | Ripples preserved in the Amapari Marker Band rock outcrop. Image via Mondro et al.\/ NASA\/ JPL-Caltech\/ MSSS.<\/figcaption><\/figure>\n Evidence for past life?<\/h3>\n
On Earth, some microbes use these very same metal minerals as food and energy sources. The mineral deposits by themselves don\u2019t prove past microbial life. But they do show that conditions were suitable for life on Mars to thrive, if it ever existed.<\/p>\n
Gasda said:<\/p>\n
\n
Given the exciting astrobiological implications raised by the Amapari Marker Band, these types of materials should be prioritized for future Curiosity chemistry analysis.<\/p>\n<\/blockquote>\n
Interestingly, the deposits are high up on the slopes of Mount Sharp. As the former lake dried out over time, the remaining pockets of water could still have supported life. <\/p>\n
The paper explains:<\/p>\n
\n
What is most surprising about this discovery is that the rover was exploring rocks that were deposited during this time period on Mars where the climate was changing from wet to dry. The rocks just below the layers with preserved ripples are indicative of drier conditions persisting on the surface of Mars. This shallow lake formed as at least part of a deposit that spans most of the sedimentary rock mound within the crater, that became deeper over time. A deep lake such as this one can have chemical gradients and would have favorable conditions for life.<\/p>\n<\/blockquote>\n
![\"Smirking](\"https:\/\/earthsky.org\/upl\/2026\/04\/Patrick-Gasda-Los-Alamos-National-Laboratory-University-of-New-Mexico.jpg\")
Lead author Patrick Gasda is a ChemCam Instrument science team member from the University of New Mexico and research scientist at Los Alamos National Laboratory. Image via University of New Mexico.<\/figcaption><\/figure>\n Zapping rocks with a laser<\/h3>\n
Wondering how Curiosity analyzes the rocks? It zaps them with a laser. The technique, called laser-induced breakdown spectroscopy<\/em>, works by vaporizing a small portion of the sample into plasma, or an incredibly hot cloud of exited, broken-apart atoms. ChemCam then analyses the light coming from this cloud to determine what elements are in the rock. In this case, it discovered a collection of metals that, on Earth, are found together in lakes.<\/p>\n
Most diverse organic molecules ever seen on Mars<\/h3>\n
Just a few days ago, NASA also reported that Curiosity has found the most diverse collection of organic molecules ever seen on Mars. Overall, it found 21 types of organics in a rock called Mary Anning. Seven of those had never been seen before, until now.<\/p>\n
And last year, Curiosity also discovered the most complex organic molecules ever found on Mars so far. Scientists think they are the remains of fatty acids.<\/p>\n
\u2018Dragon scales\u2019 in Gale crater<\/h3>\n
Curiosity also recently found some unusual dragon scales formations in Gale crater. The rover has seen similar ones before, but not this many in one location. This is the largest amount of these scales ever seen so far. Curiosity came across them near Antofagasta, a relatively young, 33-foot (10-meter) wide impact crater located on the slopes of Mount Sharp. <\/p>\n
Abigail Fraeman, a planetary scientist at the Jet Propulsion Laboratory, said:<\/p>\n
\n
Many of the rocks we\u2019ve driven over have these incredible textures, thousands of honeycomb-shaped polygons crisscross their surface. We\u2019ve seen polygon-patterned rocks like these before, but they didn\u2019t seem quite this dramatically abundant.<\/p>\n<\/blockquote>\n
Scientists don\u2019t yet know exactly how these features formed. But similar ones seen before were most likely created by drying mud. So they could have formed as the lake or other small bodies of water dried up billions of years ago in a wet-dry cycle.<\/p>\n
![\"Brownish](\"https:\/\/earthsky.org\/upl\/2026\/04\/dragon-scales-Antofagasta-Gale-crater-Mars-Curiosity-rover.jpg.jpeg\")
View larger. The Curiosity rover also recently came across more dragon scales. These are polygon-shaped features on rocks that look a lot like large, fossilized reptile scales. The rover has seen similar ones before, but this is the largest amount of them ever seen in one place. Image via NASA\/ JPL-Caltech\/ MSSS\/ Kevin M. Gill).<\/figcaption><\/figure>\n ![\"Black](\"https:\/\/earthsky.org\/upl\/2026\/04\/dragon-scales-Antofagasta-Gale-crater-Mars-Curiosity-rover-April-7-2026.jpg\")
View larger. | Another view of some of the dragon scales, seen by Curiosity on April 7, 2026. Image via NASA\/ JPL-Caltech\/ MSSS.<\/figcaption><\/figure>\n Bottom line: NASA\u2019s Curiosity rover has found yet more evidence for an ancient lake on Mars. Metallic minerals in preserved rock ripples provide the clues.<\/p>\n
Source: Amapari Marker Band Metal-Enrichments: Potential Mechanisms and Implications for Surface and Subsurface Water and Weathering in Gale Crater<\/p>\n
Via Los Alamos National Laboratory<\/p>\n
Read more: New organics on Mars raise questions about ancient life<\/p>\n
Read more: Curiosity rover spots signs of ancient megafloods on Mars<\/p>\n
<\/div>\n
\n - The rover found the highest concentrations of iron, manganese and zinc<\/strong> ever seen in one place on Mars. The metal minerals are in well-preserved ripples in rocks.<\/li>\n