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• Sensor(s):
  Landsat 8 - OLI
• Data Date: August 15, 2024
• Visualization Date: January 27, 2025

For decades, rockhounds gathered each year at Searles Lake in the Mojave Desert of southeastern California. Wielding crowbars and pickaxes, they hunted for showy deposits of minerals such as halite, trona, calcite, and dolomite. Planetary scientists from NASA and several other institutions are finding many of the same water-soluble minerals, though their tools and destinations are worlds apart.

In September 2016, NASA launched a van-sized spacecraft, OSIRIS-REx, that traveled billions of miles to reach a small diamond-shaped asteroid named Bennu. Scientists think that this “rubble pile” asteroid, which crosses Earth’s orbit every 6 years, formed from fragments of a larger asteroid that broke apart between 1 and 2 billion years ago after a cataclysmic collision.

In September 2020, OSIRIS-REx briefly touched down on Bennu’s surface, collected 4.3 ounces of crumbly regolith, and stowed it safely before returning to Earth. The video below shows what the lumpy asteroid looked like as OSIRIS-REx approached it in December 2018.

In September 2023, the spacecraft released a mini-fridge-sized capsule that parachuted into Utah with the sample. Since then, scientists have been running bits of the dark, powdery sample through a gauntlet of microscopes, mass spectrometers, and CT scanners.

Their findings, described in a new report in Nature, reveal evidence of sodium- and carbonate-rich salts called evaporites. These minerals likely formed when a briny liquid gradually evaporated in the subsurface of a wet, muddy protoplanet about 4.5 billion years ago in the early days of the solar system.

An Evaporite Connection

Few places on Earth produce combinations of evaporites similar to those found in the Bennu sample. “One of the best studied is Searles Lake,” said Tim McCoy, a curator of meteorites at the Smithsonian’s National Museum of Natural History and co-lead of the study.

Although the minerals discovered on Bennu predate those at Searles Lake, they formed in similarly salty, wet conditions. The OLI (Operational Land Imager) on Landsat 8 captured the image at the top of this page on August 15, 2024, showing the mostly dry playa of the lake. The lake is named after John Wemple Searles, a prospector and borax miner who began hauling the white mineral from the lake in 1873 using mules.

A century and a half later, signs of mining still abound. A pit mine and various industrial facilities are visible in the northwestern corner of the image around Trona, a company town established in 1913 and a major source of potash used in gunpowder during World War I. Today, the colorful rectangular evaporation ponds still concentrate valuable minerals like soda ash, salt, and lithium from salt-rich brines.

“Soda lakes” like Searles Lake intrigue planetary geologists in part because they contain highly alkaline waters. With a mixture of sodium, carbonate, and chloride ions, their brines are rich in phosphates—a substance key to the development of organic molecules, including some involved in the formation of genetic material, cell membranes, and other components thought to be critical to the formation of life.

NASA scientists recently announced the discovery of organic molecules—including several that are among the ingredients needed for life—in the Bennu sample as well (see video above).

A Predictable Sequence

Water is a remarkably good solvent, meaning common salts like sodium chloride (NaCl) or calcium carbonate (CaCO₃) dissolve easily in it. At the molecular level, salts break into positively or negatively charged ions, such as sodium (Na⁺), chloride (Cl^-), or calcium (Ca⁺), and are surrounded by molecules of water when they dissolve. The opposite occurs when water is removed from brines rich with ions, which allows ions to bond and crystallize into salts.

At Searles Lake, minerals typically develop in a predictable sequence in zones akin to bathtub rings, with calcium carbonate and magnesium carbonate forming first, followed by calcium sulfate and sodium carbonate in a middle ring. The most concentrated brines deposit chlorides and fluorides of sodium and potassium in the center of the lake. Minerals can also precipitate directly from fluids without evaporation if the ion concentration is high enough, as probably happened early in the sequence.

“Precipitation occurred in both ways on Bennu’s parent body,” McCoy said. Researchers identified 11 minerals in the asteroid sample that likely formed in liquid water. Six of these—trona, halite, pirssonite, thénardite, calcite, and dolomite—are also found at Searles Lake. The scanning electron microscope image above shows a close-up of trona, a sodium carbonate mineral, found on Bennu. Each needle is under 1 micrometer wide and 5 to 10 micrometers long; a human hair is about 100 micrometers wide. At Searles Lake, trona is often processed to produce soda ash.

Editor’s Note: Read more about Searles Lake and Bennu in A Network of Dried Lakes.

• References

• The Conversation (2025, January 29) Bennu asteroid reveals its contents to scientists—and clues to how the building blocks of life on Earth may have been seeded. Accessed January 29, 2025.
• Earth Science Picture of the Day (2011, December 8) Searles Lake Pink Halite. Accessed January 29, 2025.
• Earth Science Picture of the Day (2010, December 29) Salt Saucers. Accessed January 29, 2025.
• Glavin, D., et al. (2025) Abundant ammonia and nitrogen-rich soluble organic matter in samples from asteroid (101955) Bennu. Nature Astronomy.
• Kaplan, H. et al. (2020) Bright carbonate veins on asteroid (101955) Bennu: Implications for aqueous alteration history. Science, (370), 6517
.  
• Lauretta, D. et al. (2024) Asteroid (101955) Bennu in the laboratory: Properties of the sample collected by OSIRIS-REx. Meteoritics & Planetary Science, 59(9), 2453-2486.
• McCoy, T., et al. (2025) An evaporite sequence from ancient brine recorded in Bennu samples. Nature, 637, 1072-1077.
• NASA (2025, January 29) How NASA Found the Ingredients for Life on an Asteroid. Accessed January 29, 2025.
• NASA (2025, January 29) NASA’s Asteroid Bennu Sample Reveals Mix of Life’s Ingredients. Accessed January 29, 2025.
 
• NASA (2024) OSIRIS-REx. Accessed January 29, 2025.
• NASA Scientific Visualization Studio (2025, January 29) Discoveries from Asteroid Bennu: Media Briefing Graphics. Accessed January 29, 2025.
• The New York Times (2019) What Draws Hundreds to This Lake Bed? Spellbinding Crystals. Accessed January 29, 2025.
• Smith, G. (2009) Late Cenozoic geology and lacustrine history of Searles Valley, Inyo and San Bernardino Counties, California. U.S. Geological Survey Professional Paper, 172, 115.
• Smithsonian (2025, January 29) Traces of Ancient Brine Discovered on the Asteroid Bennu Contain Minerals Crucial to Life. Accessed January 29, 2025.
• Smithsonian (2023, October 26) Smithsonian To Open First Public Display of Asteroid Bennu Sample Collected by NASA’s OSIRIS-REx Mission. Accessed January 29, 2025.
 
• Tutolo, B, & Tosca, N. (2023) Dry, Salty, and Habitable: The Science of Alkaline Lakes. Elements, 19(1), 10-14.
 
• Tutolo, B, & Tosca, N. (2023) How to Make an Alkaline Lake: Fifty Years of Chemical Divides. Elements, 19(1), 15-21.
• The University of Arizona (2024, June 26) Bennu holds the solar system’s ‘original ingredients,’ might have been part of a wet world. Accessed January 29, 2025.
• University of Washington (2024, June 26) Shallow soda lakes show promise as cradles of life on Earth. Accessed January 29, 2025.
 

NASA Earth Observatory images by Lauren Dauphin, using Landsat data from the U.S. Geological Survey. Bennu mineral sample photograph by Rob Wardell and Tim McCoy (Smithsonian Institution). Story by Adam Voiland.

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