Experiments measure freezing point of extraterrestrial oceans to aid search for life
This image, taken by
the Galileo spacecraft in 1996, shows two views of Jupiter’s ice-covered
satellite, Europa. The left image shows the approximate natural color while the
right is colored to accentuate features. Europa is about 3,160 kilometers
(1,950 miles) in diameter, or about the size of Earth’s moon. Source: NASA Jet Propulsion Laboratory
Researchers from the University of Washington and the
University of California, Berkeley have conducted experiments that measured the
physical limits for the existence of liquid water in icy extraterrestrial
worlds. This blend of geoscience and engineering was done to aid in the
search for extraterrestrial life and the upcoming robotic exploration of oceans
on moons of other planets.
The results were recently published in Cell Reports
Physical Sciences.
“The more a liquid is stable, the more promising it is
for habitability,” said co-corresponding author Baptiste Journaux, an
acting assistant professor of Earth and space sciences at the UW. “Our
results show that the cold, salty, high-pressure liquids found in the deep
ocean of other planets’ moons can remain liquid to much cooler temperature than
they would at lower pressures. This extends the range of possible habitats on
icy moons, and will allow us to pinpoint where we should look for
biosignatures, or signs of life.”
Jupiter and Saturn’s icy moons — including
Europa, Ganymede and Titan — are leading candidates within our solar system for
hosting extraterrestrial life. These ice-encrusted moons are thought to harbor
enormous liquid oceans, up to several dozen times the volume of oceans on
Earth.
“Despite its designation as the ‘blue marble,’ Earth
is remarkably dry when compared to these worlds,“ Journaux said.
The oceans on these moons may contain various types of salts and are expected to range from about 100 miles deep, on Europa, to more than 400 miles deep, on Titan.
“We know that water supports life, but the major part
of the oceans on these moons are likely below zero degrees Celsius and at
pressures higher than anything experienced on Earth,” Journaux said. “We needed
to know how cold an ocean can get before entirely freezing, including in its
deepest abyss.”
The study focused on eutectics, or the lowest
temperature that a salty solution can remain liquid before entirely freezing.
Salt and water are one example — salty water remains liquid below the freezing
temperature of pure water, one of the reasons people sprinkle salt on roads in
winter to avoid the formation of ice.
The experiments used UC Berkeley equipment originally
designed for the future cryopreservation of organs for medical applications and
for food storage. For this research, however, the authors used it to simulate
the conditions thought to exist on other planets’ moons.
Journaux, a planetary scientist and expert on the
physics of water and minerals, worked with UC Berkeley engineers to test
solutions of five different salts at pressures up to 3,000 times atmospheric
pressure, or 300 megapascals — about three times the pressure in Earth’s
deepest ocean trench.
“Knowing the lowest temperature possible for salty
water to remain a liquid at high pressures is integral to understanding how
extraterrestrial life could exist and thrive in the deep oceans of these icy
ocean worlds,” said co-corresponding author Matthew Powell-Palm, who did the
work as a postdoctoral researcher at UC Berkeley, also co-founder and CEO of
the cryopreservation company BioChoric, Inc.
Journaux recently started working with NASA’s Dragonfly mission team, which will send a rotorcraft in 2027
to Saturn’s largest moon, Titan. NASA also is leading the Europa Clipper mission in 2024 to explore Europa,
one of the many moons orbiting Jupiter. Meanwhile, the European Space Agency in
2023 will send its JUICE spacecraft, or Jupiter Icy Moons Explorer, to explore three of Jupiter’s largest moons:
Ganymede, Callisto and Europa.
“The new data obtained from this study may help
further researchers’ understanding of the complex geological processes observed
in these icy ocean worlds,” Journaux said.
Other authors are Boris Rubinsky, Brooke Chang,
Anthony Consiglio, Drew Lilley and Ravi Prasher, all at UC Berkeley. The study
was funded by the National Science Foundation and NASA.
Source: University
of Washington