Research bolsters case for a present-day subsurface ocean on Pluto

Research bolsters case for a present-day subsurface ocean on Pluto
The New Horizons spacecraft spied extensional faults on Pluto, a sign that the dwarf planet has undergone a global expansion possibly due to the slow freezing of a subsurface ocean. A new analysis by Brown University scientists bolsters that idea, and suggests that ocean is likely still there today. Credit: NASA/JHUAPL/SwRI

When the NASA's New Horizons spacecraft buzzed by Pluto last year, it revealed tantalizing clues that the dwarf planet might have—or had at one time—a liquid ocean sloshing around under its icy crust. According to a new analysis led by a Brown University Ph.D. student, such an ocean likely still exists today.

The study, which used a thermal evolution model for Pluto updated with data from New Horizons, found that if Pluto's had frozen into oblivion millions or billions of years ago, it would have caused the entire planet to shrink. But there are no signs of a global contraction to be found on Pluto's surface. On the contrary, New Horizons showed signs that Pluto has been expanding.

"Thanks to the incredible data returned by New Horizons, we were able to observe tectonic features on Pluto's surface, update our thermal evolution model with new data and infer that Pluto most likely has a subsurface ocean today," said Noah Hammond, a graduate student in Brown's Department of Earth, Environmental and Planetary Sciences, and the study's lead author.

The research, which Hammond coauthored with advisors Amy Barr of the Planetary Science Institute in Arizona and Brown University geologist Marc Parmentier, is in press in Geophysical Research Letters.

The pictures New Horizons sent back from its close encounter with the Kuiper Belt's most famous denizen showed that Pluto was much more than a simple snowball in space. It has an exotic surface made from different types of ices—water, nitrogen and methane. It has mountains hundreds of meters high and a vast heart-shaped plain. It also has giant tectonic features—sinuous faults hundreds of kilometers long as deep as 4 kilometers. It was those tectonic features that got scientists thinking that a subsurface ocean was a real possibility for Pluto.

"What New Horizons showed was that there are extensional tectonic features, which indicate that Pluto underwent a period of global expansion," Hammond said. "A that was slowly freezing over would cause this kind of expansion."

Scientists think that there may have been enough heat-producing radioactive elements within Pluto's rocky core to melt part of the planet's . Over time in the frigid Kuiper belt, that melted portion would eventually start to refreeze. Ice is less dense than water, so when it freezes, it expands. If Pluto had on ocean that was frozen or in the process of freezing, extensional tectonics on the surface would result, and that's what New Horizons saw.

There aren't many other ways on Pluto to get such features. One way might have been through a gravitational tug of war with its moon, Charon. But the active gravitational dynamics between the two have long since wound down, and some of the tectonics look fairly fresh (on a geologic timescale). So, many scientists believe that an ocean is the strongest scenario.

But if Pluto had an ocean, what is its fate today? Could the freezing process still be going on, or did the ocean freeze solid a billion years ago?

That's where the thermal evolution model run by Hammond and his colleagues comes in. The model includes updated data from New Horizons on Pluto's diameter and density, key parameters in understanding the dynamics in Pluto's interior. The model showed that because of the low temperatures and high pressure within Pluto, an ocean that had completely frozen over would quickly convert from the normal ice we all know to a different phase called ice II. Ice II has a more compact crystalline structure than standard ice, so an ocean frozen to ice II would occupy a smaller volume and lead to a global contraction on Pluto, rather than an expansion.

"We don't see the things on the surface we'd expect if there had been a global contraction," Hammond said. "So we conclude that ice II has not formed, and therefore that the ocean hasn't completely frozen."

There are a few caveats, the researchers point out. The formation of ice II is dependent on the thickness of Pluto's ice shell. Ice II only forms if the shell is 260 kilometers thick or more. If the shell is thinner than that, the ocean could have frozen without forming ice II. And if that were the case the ocean could have frozen completely without causing contraction.

However, the researchers say there's good reason to believe that the ice shell is more than 260 kilometers. Their updated model suggests that Pluto's ice shell is actually closer to 300 or more kilometers thick. In addition, the nitrogen and methane ices that New Horizons found on the surface bolster the case for a thick ice shell.

"Those exotic ices are actually good insulators," Hammond said. "They may be helping Pluto from losing more of its heat to space."

Taken together, the new model bolsters the case for an ocean environment in the furthest reaches of the solar system.

"That's amazing to me," Hammond said. "The possibility that you could have vast liquid water ocean habitats so far from the sun on Pluto—and that the same could also be possible on other Kuiper belt objects as well—is absolutely incredible."


Explore further

Image: The dark side of Pluto

More information: Noah P. Hammond et al. Recent Tectonic Activity on Pluto Driven by Phase Changes in the Ice Shell, Geophysical Research Letters (2016). DOI: 10.1002/2016GL069220
Journal information: Geophysical Research Letters

Provided by Brown University
Citation: Research bolsters case for a present-day subsurface ocean on Pluto (2016, June 21) retrieved 27 May 2019 from https://phys.org/news/2016-06-bolsters-case-present-day-subsurface-ocean.html
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Jun 21, 2016
They must not be aware that ice increases in volume when frozen.

Jun 21, 2016
You didn't read the article properly...... They are talking about ICE II - This occupies a SMALLER volume than ordinary ice.

Jun 21, 2016
Its also unlikely to be pure water ice with so much nitrogen and methane present. I couldnt quickly find anything on whether non-pure water freezes differently. At very low temperatures and under pressure water ice does not expand the same as on Earth, and it tends to be denser.

Jun 21, 2016
I agree that ice II would contract but not beyond the original volume of water it started as. Ice Ih on the other hand has had results that show a compression beyond the original volume but ICE IH apparently does not form naturally under these conditions. So the result would not be a contraction but an expansion and then a return to the original volume however the ice above the thin layer of ICE II would still expand ultimately giving an increase in volume still. This article is dubious.

Jun 21, 2016
Passes a golden period science now come fairy tales and stories for little children.
"Scientists think that there may have been enough heat-producing radioactive elements" -210 ° C, the highest temperature, however is not low enough to cooled fiction of the "smart" heads.

Jun 21, 2016
Also the small size of Pluto (very low gravity) and the lack of any atmospheric pressure would prevent large amounts of ICE II to be formed.

Jun 22, 2016
@PoppaJ. you didn't read the article.
They must not be aware that ice increases in volume when frozen.

They are. They explicitely point out that the surface of Pluto shows signs of expansion.
I agree that ice II would contract but not beyond the original volume of water it started as.

Why are you even bringing that up? They state there are no signs of contraction *at all*, so the question to what volume it would or could contract is never raised.
Also the small size of Pluto (very low gravity) and the lack of any atmospheric pressure would prevent large amounts of ICE II to be formed.

No signs of contraction, no Ice II. What is your point?

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