Scientists detect oxygen in noxious atmosphere of Venus
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[November 09, 2023]
By Will Dunham
WASHINGTON (Reuters) - Oxygen accounts for about 21% of Earth's air,
with the rest of our atmosphere primarily nitrogen. And most living
things - including people, as we well know - need oxygen to survive.
Earth's planetary neighbor Venus offers quite a different story. Its
thick and noxious atmosphere is dominated by carbon dioxide - 96.5% -
with lesser amounts of nitrogen and trace gases. Oxygen is nearly
absent. In fact, with Venus getting far less scientific attention than
other planets such as Mars, the direct detection of its oxygen has
remained difficult.
Using an instrument aboard the SOFIA airborne observatory - a Boeing
747SP aircraft modified to carry an infrared telescope in a joint
project between NASA and the German Aerospace Center - scientists have
now detected atomic oxygen in a thin layer sandwiched between two other
layers of the Venusian atmosphere.
They noted that this atomic oxygen, which consists of a single oxygen
atom, differs from molecular oxygen, which consists of two oxygen atoms
and is breathable.
The researchers directly detected oxygen for the first time on the side
of Venus facing the sun - where it actually is produced in the
atmosphere - as well as detecting it on the side facing away from the
sun, where it previously was spotted by a ground-based telescope in
Hawaii. Venus rotates much more slowly than Earth.
"The Venus atmosphere is very dense. The composition is also very
different from Earth," said German Aerospace Center physicist
Heinz-Wilhelm Hübers, lead author of the study published in the journal
Nature Communications.
The thick atmosphere on the second planet from the sun traps in heat in
a runaway greenhouse effect.
"Venus is not hospitable, at least for organisms we know from Earth,"
Hübers added.
The oxygen is produced on the planet's day side by ultraviolet radiation
from the sun that breaks down atmospheric carbon dioxide and carbon
monoxide into oxygen atoms and other chemicals, the researchers said.
Some of the oxygen is then transported by winds to the Venusian night
side.
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Data from NASA's Magellan spacecraft and Pioneer Venus Orbiter is
used in an undated composite image of the planet Venus.
NASA/JPL-Caltech/Handout via REUTERS/File Photo
"This detection of atomic oxygen on Venus is direct proof for the
action of photochemistry - triggered by solar UV radiation - and for
the transport of its products by the winds of Venus' atmosphere,"
said astrophysicist and study co-author Helmut Wiesemeyer of the Max
Planck Institute for Radio Astronomy in Germany.
"On Earth, our life-protecting stratospheric ozone layer represents
a well-known example of such photochemistry," Wiesemeyer added.
On Venus, there is a layer of clouds containing sulfuric acid up to
a height of about 40 miles (65 km) above the planetary surface, with
hurricane-force winds blowing in the opposite direction of the
planet's rotation. About 75 miles (120 km) above the surface, strong
winds blow in the same direction as the planet's rotation.
The oxygen was found to be concentrated between those two ferocious
layers, at an altitude about 60 miles (100 km). The oxygen's
temperature was found to range from about minus 184 degrees
Fahrenheit (minus 120 degrees Celsius) on the planet's day side to
minus 256 degrees Fahrenheit (minus 160 degrees Celsius) on its
night side.
Methods used previously to detect Venusian oxygen on the day side
were indirect, based on measurements of other molecules in
combination with photochemical models.
Venus, with a diameter of about 7,500 miles (12,000 km), is slightly
smaller than Earth. In our solar system, Earth resides comfortably
within the "habitable zone" around the sun - the distance considered
not too close and not too far from a star to be able to host life,
with Venus near the inner boundary and Mars close to the outer edge.
"We are still at the beginning of understanding the evolution of
Venus and why it is so different from Earth," Hübers said.
(Reporting by Will Dunham, Editing by Rosalba O'Brien)
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