More evidence suggests Saturn's moon Enceladus could support life

A fresh look at data collected by NASA's Cassini spacecraft has uncovered more evidence that Saturn's moon Enceladus may be able to support life, with additional complex organic molecules identified from the geyser-like jets of ice grains that spew into space from this small icy world's subsurface ocean.

Researchers reexamined in great detail data obtained when Cassini conducted its closest flyby of Enceladus in 2008, including when it flew directly through plumes of ice grains and gases erupting from the ice-encrusted moon's surface through fractures near its south pole. In doing so, they were able to gain a clearer picture of the moon's subsurface chemistry.

In addition to confirming the presence of certain organic molecules, including precursors for amino acids - the building blocks of proteins, the large and complex molecules essential for life - previously detected in the plumes, they found new classes of organic molecules not spotted before.

"We have found several categories of organic - meaning primarily carbon-containing - molecules that span a range of structures and chemical properties," said Nozair Khawaja, a planetary scientist at Freie Universität Berlin and lead author of the study published this week in the journal Nature Astronomy.

These are the type of molecules that could be involved under the right circumstances in the processes leading to the formation of more complex organic compounds that are essential components for life.

"Such compounds are believed to be intermediates in the synthesis of more complex molecules, which could be potentially biologically relevant. It is important to note, however, that these molecules can be formed abiotically as well without any interaction with life on Earth," Khawaja said.

Enceladus is considered one of the most intriguing places in our solar system to look for possible life beyond Earth. Named after a giant in ancient Greek mythology, it is one of the innermost moons of the ringed gas giant Saturn, our solar system's second-largest planet. It has a diameter of 313 miles (504 km) and orbits Saturn at a distance of roughly 148,000 miles (238,000 km).

Scientists believe Enceladus possesses the chemical ingredients needed for life and has hydrothermal vents releasing hot, mineral-rich water into its ocean, the same type of environment that may have spawned Earth's first living organisms. Its ocean resides under a crust of ice about 12-19 miles (20-30 km) thick.

"First of all, we did not find life on Enceladus and we did not find any biosignatures," Khawaja said, referring to anything indicative of life, past or present.

"Even if such things exist there, I doubt that we would find it in the data of Cassini's instruments, which were decades-old technology. However, we have compelling evidence that all three keystones of habitability - liquid water, an energy source and essential elements and organics - exist on Enceladus," Khawaja said.

The researchers conducted a comprehensive chemical analysis of the ice grains sampled directly from the plume during Cassini's flyby at a speed of about 40,250 miles (64,800 km) per hour. These grains are tiny bits of frozen water from the subsurface ocean that had been ejected only minutes earlier, so they were not altered over time by intense space radiation like the ice grains from Enceladus that form a ring around Saturn that traces the moon's orbital path.

The chemical properties of the plume grains thus reflected complex chemical reactions occurring in the ocean.

The European Space Agency is planning a future mission to return to Enceladus.

"Enceladus is, and should be ranked, as the prime target to explore habitability and search whether there is life or not," Khawaja said.