Ingredients for Life Revealed in
Meteorites That Fell to Earth
Study, based in part at Berkeley Lab, also suggests dwarf planet in asteroid belt may be a source of rich organic matter
By Glenn Roberts, Jr.
Ceres False Color Image (NASA)
The
study, published Jan. 10 in the journal Science Advances,
provides the first comprehensive chemical exploration of organic matter and
liquid water in salt crystals found in Earth-impacting meteorites. The study
treads new ground in the narrative of our solar system’s early history and
asteroid geology while surfacing exciting possibilities for the existence of
life elsewhere in Earth’s neighborhood.
“It’s like a fly in amber,” said David Kilcoyne, a scientist at Berkeley Lab’s Advanced Light Source (ALS), which provided X-rays that were used to scan the samples’ organic chemical components, including carbon, oxygen, and nitrogen. Kilcoyne was part of the international research team that prepared the study.
U.K.
Japan
Meteorites That Fell to Earth
Study, based in part at Berkeley Lab, also suggests dwarf planet in asteroid belt may be a source of rich organic matter
By Glenn Roberts, Jr.
January 10, 2018 -- Two wayward
space rocks, which separately crashed to Earth in 1998 after circulating in our
solar system’s asteroid belt for billions of years, share something else in
common: the ingredients for life. They are the first meteorites found to
contain both liquid water and a mix of complex organic compounds such as
hydrocarbons and amino acids.
A
detailed study of the chemical makeup within tiny blue and purple salt crystals
sampled from these meteorites, which included results from X-ray experiments at
the Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley
Lab), also found evidence for the pair’s past intermingling and likely parents.
These include Ceres, a dwarf planet that is the largest object in the asteroid
belt, and the asteroid Hebe, a major source of meteorites that fall on Earth.
“It’s like a fly in amber,” said David Kilcoyne, a scientist at Berkeley Lab’s Advanced Light Source (ALS), which provided X-rays that were used to scan the samples’ organic chemical components, including carbon, oxygen, and nitrogen. Kilcoyne was part of the international research team that prepared the study.
While
the rich deposits of organic remnants recovered from the meteorites don’t
provide any proof of life outside of Earth, Kilcoyne said the meteorites’
encapsulation of rich chemistry is analogous to the preservation of prehistoric
insects in solidified sap droplets.
Queenie
Chan, a planetary scientist and postdoctoral research associate at The Open
University in the
She
added, “We’re looking at the organic ingredients that can lead to the origin of
life,” including the amino acids needed to form proteins.
If
life did exist in some form in the early solar system, the study notes that
these salt crystal-containing meteorites raise the “possibility of trapping
life and/or biomolecules” within their salt crystals. The crystals carried
microscopic traces of water that is believed to date back to the infancy of our
solar system – about 4.5 billion years ago.
Chan
said the similarity of the crystals found in the meteorites – one of which
smashed into the ground near a children’s basketball game in Texas
in March 1998 and the other which hit near Morocco
There
are also structural clues of an impact – perhaps by a small asteroid
fragment impacting a larger asteroid, Chan said.
This
opens up many possibilities for how organic matter may be passed from one host
to another in space, and scientists may need to rethink the processes that led
to the complex suite of organic compounds on these meteorites.
“Things
are not as simple as we thought they were,” Chan said.
There
are also clues, based on the organic chemistry and space observations, that the
crystals may have originally been seeded by ice- or water-spewing volcanic
activity on Ceres,
she said.
“Everything
leads to the conclusion that the origin of life is really possible elsewhere,”
Chan said. “There is a great range of organic compounds within these
meteorites, including a very primitive type of organics that likely represent
the early solar system’s organic composition.”
Chan
said the two meteorites that yielded the 2-millimeter-sized salt crystals were
carefully preserved at NASA’s Johnson Space Center
in Texas
“What
makes our analysis so special is that we combined a lot of different
state-of-the-art techniques to comprehensively study the organic components of
these tiny salt crystals,” Chan said.
Yoko
Kebukawa, an associate professor of engineering at Yokohama
National University
in Japan , carried out
experiments for the study at Berkeley Lab’s ALS in May 2016 with Aiko Nakato, a
postdoctoral researcher at Kyoto University in Japan
The
beamline equipped with this X-ray microscope (a scanning transmission X-ray
microscope, or STXM) is used in combination with a technique known as XANES
(X-ray absorption near edge structure spectroscopy) to measure the presence of
specific elements with a precision of tens of nanometers (tens of billionths of
a meter).
“We
revealed that the organic matter was somewhat similar to that found in
primitive meteorites, but contained more oxygen-bearing chemistry,” Kebukawa
said. “Combined with other evidence, the results support the idea that the
organic matter originated from a water-rich, or previously water-rich parent
body – an ocean world in the early solar system, possibly Ceres.”
Kebukawa
also used the same STXM technique to study samples at the Photon Factory, a
research site in
Chan
noted that there are some other well-preserved crystals from the meteorites
that haven’t yet been studied, and there are plans for follow-up studies to
identify if any of those crystals may also contain water and complex organic
molecules.
Kebukawa
said she looks forward to continuing studies of these samples at the ALS and
other sites: “We may find more variations in organic chemistry.”
The
Advanced Light Source is a DOE Office of Science User Facility.
http://newscenter.lbl.gov/2018/01/10/organic-meteorites/
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