The icy
crust enveloping Saturn’s moon Enceladus has long fascinated astronomers.
Evidence collected by NASA and the European Space Agency’s Cassini-Huygens
spacecraft suggests the shell could be hiding a massive subsurface ocean made
up of briny water underneath it — which, tantalizingly, could potentially harbor
life.
According to
a new study by a team from the University of Arizona and Paris Sciences &
Letters University, published in the journal Nature Astronomy last month,
Cassini’s observations that found Enceladus is expelling plumes of methane gas
suggest that the moon’s subsurface oceans may be habitable to Earth-like
microorganisms.
“We wanted to know: Could Earthlike microbes that ‘eat’ the dihydrogen and produce methane explain the surprisingly large amount of methane detected by Cassini?” asked Regis Ferriere, an associate professor at the University of Arizona and a lead author of the study, in a statement.
But figuring
out the answer for sure is far from easy.
“Searching for such microbes, known as methanogens, at Enceladus’ seafloor would require extremely challenging deep-dive missions that are not in sight for several decades,” he added.
The team
constructed mathematical models to see if methanogenesis could account for the
data collected by Cassini. Their conclusion: microbial hydrothermal vent
activity — or processes that would involve extraterrestrial microorganisms —
could explain the methane detected by Cassini.
On Earth,
hydrothermal activity is caused by cold seawater dipping into the ocean floor,
where it gets warmed up by local sources of heat like magma. This water then
gets expelled out of vents in the ocean floor, a process that drips methane
into the water over time.
Most of this
methane is released by microorganisms that use the heat as a source of energy,
turning carbon dioxide into methane.
According to
their computer simulations, the researchers found that similar conditions could
exist on Enceladus.
“In summary, not only could we evaluate whether Cassini’s observations are compatible with an environment habitable for life, but we could also make quantitative predictions about observations to be expected, should methanogenesis actually occur at Enceladus’ seafloor,” Ferriere said in the statement.
In fact,
without the existence of biological sources of methane production, the levels
of methane observed by Cassini couldn’t be matched using their models.
Still, it
would be premature to draw any definite conclusions.
“Obviously, we are not concluding that life exists in Enceladus’ ocean,” Ferriere added. “Rather, we wanted to understand how likely it would be that Enceladus’ hydrothermal vents could be habitable to Earthlike microorganisms. Very likely, the Cassini data tell us, according to our models.”
We simply
don’t have enough data to go off of just yet.
“In other words, we can’t discard the ‘life hypothesis’ as highly improbable,” Ferriere said. “To reject the life hypothesis, we need more data from future missions.”
The
researchers also didn’t rule out other possible abiotic processes that could
explain the methane data. For instance, the chemical breakdown of primordial
organic matter in the moon’s core could be causing significant amounts of
methane to be ejected.
It’s
exciting new research that goes to show how little we know about Saturn’s icy
moons, despite Cassini’s extensive legacy. Perhaps one day, another mission
will even get a firsthand look.
READ MORE:
Methane in the plumes of Saturn’s moon Enceladus: Possible signs of life?
[University of Arizona]