Acidic Europa May Eat Away at Chances for Complex Life
Europa, which is roughly the size of Earth's moon, could possess an ocean about 100 miles deep (160 kilometers). This ocean is overlain by an icy crust of unknown thickness, although some estimates are that it could be only a few miles thick.
Since there is life virtually wherever there is liquid water on Earth, for many years scientists have entertained the notion that this Jovian moon could support extraterrestrials. Recent findings even suggest its ocean could be loaded with oxygen, enough to support millions of tons worth of marine life like the kinds that exist on Earth. Researchers have proposed missions to penetrate Europa's outer shell to look for life in its ocean, although others have suggested that fossils of marine life on Europa could be available right on the surface for prospectors to find, given how water apparently regularly gets pushed up from below.
However, chemicals found on the surface of Europa might jeopardize any chances of life evolving there, scientists find. The resulting level of acidity in its ocean "is probably not friendly to life — it ends up messing with things like membrane development, and it could be hard building the large-scale organic polymers," said researcher Matthew Pasek, an astrobiologist at the University of South Florida.
The oxidants on Europa's surface are likely carried downward in potentially substantial quantities by the same churning that causes water to rise from below. Oxidants could be of great use to any life in Europa's ocean — for example, oxygen was pivotal to how complex life evolved on Earth.
However, oxidants from Europa's surface might react with sulfides and other compounds in this moon's ocean before life could nab it, generating sulfuric and other acids, investigators said. If this has occurred for just about half of Europa's lifetime, not only would such a process rob the ocean of life-supporting oxidants, but it could become relatively corrosive, with a pH of about 2.6, "about the same as your average soft drink," Pasek said. (In a recent lawsuit against PepsiCo, the defendant claimed to have found a mouse in a can of Mountain Dew. PepsiCo countered that the 3.43 pH of the soda would have dissolved the mouse into a jelly-like substance).
This level of acidity would be a significant challenge for life, unless organisms were to consume or sequester oxidants fast enough to ameliorate the acidification, researchers said. The ecosystem would need to evolve quickly to meet this crisis, with oxygen metabolisms and acid tolerance developing in only about 50 million years to handle the acidification.
"The microbes there have figured out ways of fighting their acidic environment," Pasek said. "If life did that on Europa, Ganymede, and maybe even Mars, that might have been quite advantageous."
Others have questioned whether or not rock in Europa's seabed might actually neutralize the effects of this acidity. Pasek does not think this is likely — even if such minerals were present, there is probably not enough of it exposed to reduce acidity by much, he said.
The calcium-based materials that bones and shells on Earth are made from might dissolve pretty readily in such an acidic environment. However, "one of the interesting possibilities is that they might have use blue phosphates as their bone material instead to evolve large organisms," Pasek said. "If you have iron phosphates, you make a pretty blue mineral called vivianite."
Pasek and Richard Greenberg detailed their findings online Jan. 27 in the journal Astrobiology
Editor's Note: this article was altered after publication to clarify that acidophiles on Earth are found in low pH environments. .