A hugely exciting paper in the journal Nature Astronomy today suggests that signs of life on Jupiter’s moon Europa may be relatively easy to find, as it may exist just centimeters below the surface.
Led by Tom Nordheim from NASA’s Jet Propulsion Laboratory in California, the study suggests that near the poles of Europa, amino acids could exist for 10 million years just 1 to 3 centimeters (0.4-1.2 inches) below the surface. Towards the equator, this increases to several tens of centimeters.
“Europa is really interesting to planetary scientists because we think that life could exist within its ocean, which is located miles beneath its icy surface,” Nordheim told IFLScience. “What’s really exciting is that we think that material from Europa’s ocean might have been transported up to the surface.”
The major issue though is the amount of radiation blasted onto Europa by Jupiter. Standing on the surface is equivalent to “standing inside a particle accelerator,” said Nordheim, meaning that any biological material from the ocean would likely be destroyed.
However, it appears that some biological material can survive at these relatively small distances below the surface. That’s based on modeling from the scientists, which looked at the global pattern of energetic electrons hitting the surface.
The team found that some regions on Europa may experience a dose of about 74 million grays (Gy) from Jupiter’s radiation. Earth’s most radiation-resistant bacteria, Deinococcus radiodurans, can only survive up to 5,000 Gy, so we can probably rule out finding any living organisms. But signs of life could survive.
In an accompanying News and Views article, John Cooper from NASA’s Goddard Space Flight Center said we could find “biochemical fragments of past life mixed into the surface ice”, such as amino acids, at these levels. This means an upcoming mission, like NASA’s proposed Europa Lander, would only have to scratch slightly below the surface to find biosignatures.
The levels of radiation are less at the poles than at the equator, which is why biological material here might be easier to reach. Searching for actual organisms might be a bit ambitious, but certainly the chances of finding biosignatures look enticing.
And if a probe landed in a region with fresh material, deposited within the last 1,000 years, we could even discover “fully pristine biosignatures” that had not been too damaged by radiation yet, said Cooper.