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Nachrichten, Termine, Experten
With the OSIRIS-REx space probe, the NASA space agency succeeded in collecting some material from the surface of asteroid Bennu, which arrived on Earth in a small capsule in 2023. The analysis of the material by more than 40 scientific teams worldwide – including the team led by Prof. Frank Brenker from Goethe University – revealed a number of organic substances that form the basis for biomolecules. In addition, the minerals in the sample also indicate that the protoplanet from which Bennu originated once had liquid, salty water. Thus, this protoplanet possessed both ingredients for life and potential habitats.
FRANKFURT. It took two years for NASA’s OSIRIS-REx space probe to return from asteroid Bennu before dropping off a small capsule as it flew past Earth, which was then recovered in the desert of the U.S. state of Utah on September 24, 2023. Its contents: 122 grams of dust and rock from asteroid Bennu. The probe had collected this sample from the surface of the 500-metre agglomerate of unconsolidated material in a touch-and-go maneuver that took just seconds. Since the capsule protected the sample from the effects of the atmosphere, it could be analyzed in its original state by a large team of scientists from more than 40 institutions around the world.
The partners in Germany were geoscientists Dr. Sheri Singerling, Dr. Beverley Tkalcec and Prof. Frank Brenker from Goethe University Frankfurt. They examined barely visible grains of Bennu using the transmission electron microscope of the Schwiete Cosmochemistry Laboratory, set up at Goethe University only a year ago with the support of the Dr. Rolf M. Schwiete Foundation, the German Research Foundation and the State of Hesse. Its goal: to reconstruct the processes that took place on Bennu’s protoplanetary parent body more than four billion years ago and ultimately led to the formation of the minerals that exist today. The Frankfurt scientists succeeded in doing this by analyzing the mineral grains’ exact structure and determining their chemical composition at the same time. They also carried out trace element tomography of the samples at accelerators such as DESY (Deutsches Elektronen-Synchrotron) in Hamburg.
“Together with our international partner teams, we have been able to detect a large proportion of the minerals that are formed when salty, liquid water – known as brine – evaporates more and more and the minerals are precipitated in the order of their solubility,” explains Dr. Sheri Singerling, who manages the Schwiete Cosmo Lab. In technical terms, the rocks that form from such precipitation cascades are called evaporites. They have been found on Earth in dried-out salt lakes, for example.
“Other teams have found various precursors of biomolecules such as numerous amino acids in the Bennu samples,” reports Prof. Frank Brenker. “This means that Bennu’s parent body had some known building blocks for biomolecules, water and – at least for a certain time – energy to keep the water liquid.” However, the break-up of Bennu’s parent body interrupted all processes very early on and the traces that have now been discovered were preserved for more than 4.5 billion years.
“Other celestial bodies such as Saturn's moon Enceladus, or the dwarf planet Ceres have been able to evolve since then and are still very likely to have liquid oceans or at least remnants of them under their ice shells,” says Brenker. “Since this means that they have a potential habitat, the search for simple life that could have evolved in such an environment is a focus of future missions and sample studies.”
OSIRIS-REx
NASA’s Goddard Space Flight Center in Greenbelt, Maryland, provided overall mission management, systems engineering, and the safety and mission assurance for OSIRIS-REx. Dante Lauretta of the University of Arizona, Tucson, is the principal investigator. The university leads the science team and the mission’s science observation planning and data processing. Lockheed Martin Space in Littleton, Colorado, built the spacecraft and provided flight operations.
Picture downloads:
http://www.uni-frankfurt.de/165813816
Captions:
1) Studies of the smallest amounts of material: Cosmochemist Professor Frank Brenker shows three grains of a meteorite that the Goethe University team used to test research methods in advance. The quantity and type corresponded to the material from the asteroid Bennu. Photo: Uwe Dettmar for Goethe University.
2) A few specks of dust: The samples analyzed in the transmission electron microscope of the Schwiete Cosmo Lab at Goethe University are barely visible. Arrows indicate three of the samples. Photo without arrows: NASA
3) In the lab: Dr. Sheri Singerling inserts a sample carrier into the transmission electron microscope of the Schwiete Cosmo Lab. Photo: Uwe Dettmar for Goethe University
4) In the lab (2): Dr. Sheri Singerling analyzing the TEM images of the material from Bennu. Photo: Uwe Dettmar for Goethe University
NASA photo and image material:
https://science.nasa.gov/mission/osiris-rex
and
https://svs.gsfc.nasa.gov/gallery/osirisrex/
Picture downloads:
http://www.uni-frankfurt.de/165813816
Captions:
1) Studies of the smallest amounts of material: Cosmochemist Professor Frank Brenker shows three grains of a meteorite that the Goethe University team used to test research methods in advance. The quantity and type corresponded to the material from the asteroid Bennu. Photo: Uwe Dettmar for Goethe University.
2) A few specks of dust: The samples analyzed in the transmission electron microscope of the Schwiete Cosmo Lab at Goethe University are barely visible. Arrows indicate three of the samples. Photo without arrows: NASA
3) In the lab: Dr. Sheri Singerling inserts a sample carrier into the transmission electron microscope of the Schwiete Cosmo Lab. Photo: Uwe Dettmar for Goethe University
4) In the lab (2): Dr. Sheri Singerling analyzing the TEM images of the material from Bennu. Photo: Uwe Dettmar for Goethe University
Professor Frank E. Brenker
NanoGeoscience / Cosmochemistry
Institute for Geosciences
Goethe University Frankfurt, Germany
Tel.: (069)-798 40134
f.brenker@em.uni-frankfurt.de
Tim J. McCoy et al.: An evaporite sequence from ancient brine recorded in Bennu samples. Nature (2025) https://doi.org/10.1038/s41586-024-08495-6
https://doi.org/10.1038/s41550-024-02472-9 Daniel P. Glavin et al.: Abundant ammonia and nitrogen-rich soluble organic matter in samples from asteroid (101955) Bennu Nature Astronomy (2025)
https://aktuelles.uni-frankfurt.de/english/study-of-asteroid-bennu-goethe-univer... Inauguration of Schwiete Cosmo Lab (October 2023)
Studies of the smallest amounts of material: Cosmochemist Professor Frank Brenker shows three grains ...
Uwe Dettmar
Goethe University Frankfurt
In the lab: Dr. Sheri Singerling analyzing the TEM images of the material from Bennu.
Uwe Dettmar
Goethe University Frankfurt
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Studies of the smallest amounts of material: Cosmochemist Professor Frank Brenker shows three grains ...
Uwe Dettmar
Goethe University Frankfurt
In the lab: Dr. Sheri Singerling analyzing the TEM images of the material from Bennu.
Uwe Dettmar
Goethe University Frankfurt
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