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Probing The Hydrological Cycle Of Methane Rainfall On Saturn’s Moon Titan

September 3, 2014
Image Caption: Titan's subsurface reservoirs. Credit: ESA/ATG medialab

European Space Agency

The international Cassini mission has revealed hundreds of lakes and seas spread across the icy surface of Saturn’s moon Titan, mostly in its polar regions. These lakes are filled not with water but with hydrocarbons, a form of organic compound that is also found naturally on Earth and includes methane. While most of the liquid in the lakes is thought to be replenished by rainfall from clouds in the moon’s atmosphere, the cycling of liquid throughout Titan’s crust and atmosphere is still not well understood.

A recent study led by Olivier Mousis at the Université de Franche-Comté, France, and involving colleagues at Cornell University and NASA’s Jet Propulsion Laboratory in the USA, probed the hydrological cycle of Titan by examining how Titan’s methane rainfall would interact with icy materials within underground reservoirs. They found that the formation of materials called clathrates changes the chemical composition of the rainfall runoff that fills these hydrocarbon reservoirs, leading to the formation of reservoirs of propane and ethane that may feed into some rivers and lakes.

“We knew that a significant fraction of the lakes on Titan’s surface might be connected with hidden bodies of liquid beneath Titan’s crust, but we just didn’t know how they would interact”, says Mousis. “Now, we’ve modelled the moon’s interior in great detail, and have a better idea of what these hidden lakes or oceans could be like.”

Mousis and colleagues modelled how a subsurface reservoir of liquid hydrocarbons would diffuse throughout Titan’s porous icy crust. They found that this diffusion could cause a new reservoir – formed from clathrates – to form where the bottom of the original reservoir meets layers of non-porous ice.

Clathrates are compounds in which water forms a crystal structure with small cages that trap other substances like methane and ethane. On Earth, clathrates that contain methane are found in some polar and ocean sediments. On Titan, the surface pressure and temperature allow clathrates to form when liquid hydrocarbons come into contact with water ice, a main component of the moon’s crust. These clathrates could remain stable as far down as several kilometers below the surface of Titan.

“One of the interesting properties of clathrates is that they cause fractionation – in this case, they trap and split molecules into a mix of liquid and solid phases,” adds Mousis. Because of this, astronomers have suggested that clathrates may be responsible for many unusual phenomena on Titan, including the depletion of the heavy noble gases in the moon’s atmosphere, and variations in the moon’s polar radius.

Titan’s subsurface clathrate reservoirs would interact with and fractionate the liquid methane within the original underground hydrocarbon lake, slowly changing its composition. Eventually, subsurface lakes that had come into contact with the clathrate layer would mainly be composed of either propane or ethane, depending on the type of clathrate that had formed.

Importantly, this would continue up to Titan’s surface. Lakes fed by these propane or ethane subsurface reservoirs would show the same kind of composition, whereas those fed by rainfall would be different and contain methane, nitrogen, and trace amounts of argon and carbon monoxide. “This means we would be able to look at the composition of the surface lakes and learn something about what is happening deep underground,” says Mousis.

The Cassini Solstice mission, an extension of Cassini that runs until 2017, will give scientists a chance to explore Titan’s surface lakes even more closely by performing an additional 54 close flybys of the Saturnian moon.

“Understanding Titan’s hydrological cycle is one of the most important objectives of Cassini’s extended mission,” says ESA’s Cassini-Huygens project scientist Nicolas Altobelli. “The changing seasons on Titan mean that soon we can again explore the lake-filled region at its north pole, and maybe spot seasonal phenomena we haven’t seen before. This is crucial to getting a better understanding of what lies hidden beneath Titan’s surface.”

Reference: “Equilibrium composition between liquid and clathrate reservoirs on Titan” by O. Mousis et al. is published in the journal Icarus, Volume 239, 1 September 2014; doi: 10.1016/j.icarus.2014.05.032

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Source: European Space Agency



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