Enceladus is a prime target in the search for life in the Solar System, identified by NASA as the second-highest priority site for a flagship mission in the next decade.
Despite having an ice shell many kilometers thick that would make it difficult to probe the subsurface ocean directly, Enceladus ejects ocean material as a plume of icy particles through cracks in the icy surface at the southern pole, forming the E-ring of Saturn and providing the opportunity to perform plume flythrough sampling as a measure of the composition of the subsurface ocean. Image credit: NASA / JPL-Caltech.
During its 20-year mission, NASA’s Cassini spacecraft discovered that ice plumes spew from Enceladus’ surface at approximately 400 m/s (800 mph).
These plumes provide an excellent opportunity to collect samples and study the composition of Enceladus’ oceans and potential habitability.
However, until now it was not known if the speed of the plumes would fragment any organic compounds contained within the ice grains, thus degrading the samples.
In new research, scientists at the University of California San Diego found laboratory evidence that amino acids — an important class of biosignature molecules — transported in these ice plumes can survive impact speeds of up to 4.2 km/s (2.6 miles per second), supporting their detection during sampling by spacecraft.
Beginning in 2012, they custom-built a unique aerosol impact spectrometer, designed to study collision dynamics of single aerosols and particles at high velocities.
Although not built specifically to study ice grain impacts, it turned out to be exactly the right machine to do so.
“This apparatus is the only one of its kind in the world that can select single particles and accelerate or decelerate them to chosen final velocities,” said University of California San Diego’s Professor Robert Continetti, senior author of the study.
“From several micron diameters down to hundreds of nanometers, in a variety of materials, we’re able to examine particle behavior, such as how they scatter or how their structures change upon impact.”
In 2024, NASA will launch the Europa Clipper, which will travel to Jupiter.
Europa, one of Jupiter’s largest moons, is another ocean world, and has a similar icy composition to Enceladus.
There is hope that the Clipper or any future probes to Saturn will be able to identify a specific series of molecules in the ice grains that could point to whether life exists in the subsurface oceans of these moons, but the molecules need to survive their speedy ejection from the moon and collection by the probe.
Although there has been research into the structure of certain molecules in ice particles, the study authors are the first to measure what happens when a single ice grain impacts a surface.
To run the experiment, ice grains were created using electrospray ionization, where water is pushed through a needle held at a high voltage, inducing a charge that breaks the water into increasingly smaller droplets.
The droplets were then injected into a vacuum where they freeze.
The team measured their mass and charge, then used image charge detectors to observe the grains as they flew through the spectrometer.
A key element to the experiment was installing a microchannel plate ion detector to accurately time the moment of impact down to the nanosecond.
The results showed that amino acids can be detected with limited fragmentation up to impact velocities of 4.2 km/s.
“To get an idea of what kind of life may be possible in the solar system, you want to know there hasn’t been a lot of molecular fragmentation in the sampled ice grains, so you can get that fingerprint of whatever it is that makes it a self-contained life form,” Professor Continetti said.
“Our work shows that this is possible with the ice plumes of Enceladus.”
The study also raises interesting questions for chemistry itself, including how salt affects the detectability of certain amino acids.
It is believed that Enceladus contains vast salty oceans — more than is present on Earth.
Because salt changes the properties of water as a solvent as well as the solubility of different molecules, this could mean that some molecules cluster on the surface of the ice grains, making them more likely to be detected.
“The implications this has for detecting life elsewhere in the Solar System without missions to the surface of these ocean-world moons is very exciting, but our work goes beyond biosignatures in ice grains,” Professor Continetti said.
The team’s work appears in the Proceedings of the National Academy of Sciences.
_____
Sally E. Burke et al. 2023. Detection of intact amino acids with a hypervelocity ice grain impact mass spectrometer. PNAS 120 (50): e2313447120; doi: 10.1073/pnas.2313447120
