Meteorite impacts identified as driver of moon's tenuous atmosphere
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 [August 03, 2024]
By Will Dunham
WASHINGTON Reuters) - The NASA astronauts who became the first people to
land on the moon's surface in the 1960s and 1970s also discovered a
previously unknown lunar characteristic - it has an atmosphere, though
quite tenuous. Soil samples they retrieved are now revealing the main
physical process driving this atmosphere.
By analyzing which forms of two elements - potassium and rubidium - were
present in nine tiny soil samples from five Apollo missions, researchers
determined that the lunar atmosphere was created and is sustained
primarily by the effects of meteorites, large and small, striking the
moon's surface.
"Meteorite impacts generate high temperatures ranging from 2,000-6,000
degrees Celsius (3,600-10,800 degrees Fahrenheit). These extreme
temperatures melt and vaporize rocks on the lunar surface, similar to
how heat vaporizes water, releasing atoms into the atmosphere," said
Massachusetts Institute of Technology planetary scientist and
cosmochemist Nicole Nie, lead author of the study published on Friday in
the journal Science Advances.
The lunar atmosphere is extremely thin and technically classified as an
exosphere, meaning atoms do not collide with each other because their
numbers are so sparse, in contrast to Earth's thick and stable
atmosphere.
"The Apollo missions carried instruments to the lunar surface which
detected atoms in the air," Nie said.
In 2013, NASA sent the robotic LADEE (Lunar Atmosphere and Dust
Environment Explorer) spacecraft to orbit the moon to study its
atmosphere and surface environment. It identified two processes, known
as space weathering, at work - the meteorite impacts and a phenomenon
called solar wind sputtering.
"Solar winds carry high-energy charged particles, primarily protons,
through space. When these particles impact the moon, they transfer their
energy to lunar surface atoms, causing them to be ejected from the
surface," Nie said.
Solar wind refers to the constant stream of charged particles from the
sun permeating the solar system.
LADEE did not determine the relative contributions of these two
processes to the lunar atmosphere. The new study showed that impacts
account for more than 70% of its composition, while solar wind
sputtering contributes less than 30%.
The moon has been constantly bombarded by meteorites - early in its
history by large ones that gashed the gaping craters visible on the
lunar surface and more recently by smaller ones including dust-sized
micrometeorites. Some of the atoms lofted by these impacts fly off into
space. The rest remain suspended above the surface in an atmosphere
regularly replenished as more meteorites land.
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A view of the moon over a mountain in Garmisch-Partenkirchen,
Germany, July 19, 2024. REUTERS/Angelika Warmuth/File Photo
The lunar atmosphere contains mainly argon, helium and neon, along
with potassium and rubidium and possibly other elements at lesser
levels. It extends from the moon's surface to a height of about 62
miles (100 km). Earth's atmosphere extends to approximately 6,200
miles (10,000 km).
Instead of investigating the actual atoms in the lunar atmosphere,
the researchers used lunar soil, called regolith, as a proxy. They
used an instrument called a mass spectrometer to examine the ratio
of different isotopes of potassium and rubidium in the soil.
Isotopes are atoms of the same element with slightly different
masses because of differing numbers of subatomic particles called
neutrons.
"This is possible because the lunar surface soil is interacting with
the exosphere since the formation of the moon, and the different
processes leave distinct imprints on the isotopic composition of the
lunar soil," said planetary scientist and study co-author Timo Hopp
of the Max Planck Institute for Solar System Research in Germany.
Three isotopes of potassium and two isotopes of rubidium exist.
After decades of studying the moon, scientists are still learning
about some of its basic processes.
"Many important questions about the lunar atmosphere remain
unanswered. We are now able to address some of these questions due
to advancements in technology," Nie said. "When Apollo samples were
returned from the moon in the 1970s, the isotopic compositions of
potassium and rubidium in lunar soils were measured using mass
spectrometers. However, at that time, no isotopic differences were
observed. Today's mass spectrometers offer much greater precision."
(Reporting by Will Dunham; Editing by Daniel Wallis)
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