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rfmcdonaldThe answer to the question posed in the title of Jason Major's Universe Today article is almost certainly yes.
Neptune's moon Triton is noteworthy not only as the largest moon of Neptune, captured in a hypothesized near-collision eons ago, but as a prototype for the worlds of the Kuiper Belt, the belt of icy bodies (including dwarf planets) beyond Neptune's orbit that includes the famous dwarf planet binary of Pluto and Charon. A Triton that, heated by tidal friction with Neptune and the decay of heavy elements in its core, has an ammonia-doped water ocean underneath its surface not only adds to the long list of outer Solar System bodies thought to have subsurface oceans like Jupiter's Europa and Saturn's Enceladus, but also has obvious implications for the wider Kuiper Belt.
Neptune's moon Triton is noteworthy not only as the largest moon of Neptune, captured in a hypothesized near-collision eons ago, but as a prototype for the worlds of the Kuiper Belt, the belt of icy bodies (including dwarf planets) beyond Neptune's orbit that includes the famous dwarf planet binary of Pluto and Charon. A Triton that, heated by tidal friction with Neptune and the decay of heavy elements in its core, has an ammonia-doped water ocean underneath its surface not only adds to the long list of outer Solar System bodies thought to have subsurface oceans like Jupiter's Europa and Saturn's Enceladus, but also has obvious implications for the wider Kuiper Belt.
Briefly visited by Voyager 2 in late August 1989, Triton was found to have a curiously mottled and rather reflective surface nearly half-covered with a bumpy “cantaloupe terrain” and a crust made up of mostly water ice, wrapped around a dense core of metallic rock. But researchers from the University of Maryland are suggesting that between the ice and rock may lie a hidden ocean of water, kept liquid despite estimated temperatures of -97°C (-143°F), making Triton yet another moon that could have a subsurface sea.
How could such a chilly world maintain an ocean of liquid water for any length of time? For one thing, the presence of ammonia inside Triton would help to significantly lower the freezing point of water, making for a very cold — not to mention nasty-tasting — subsurface ocean that refrains from freezing solid.
In addition to this, Triton may have a source of internal heat — if not several. When Triton was first captured by Neptune’s gravity its orbit would have initially been highly elliptical, subjecting the new moon to intense tidal flexing that would have generated quite a bit of heat due to friction (not unlike what happens on Jupiter’s volcanic moon Io.) Although over time Triton’s orbit has become very nearly circular around Neptune due to the energy loss caused by such tidal forces, the heat could have been enough to melt a considerable amount of water ice trapped beneath Triton’s crust.
Another possible source of heat is the decay of radioactive isotopes, an ongoing process which can heat a planet internally for billions of years. Although not alone enough to defrost an entire ocean, combine this radiogenic heating with tidal heating and Triton could very well have enough warmth to harbor a thin, ammonia-rich ocean beneath an insulating “blanket” of frozen crust for a very long time — although eventually it too will cool and freeze solid like the rest of the moon. Whether this has already happened or still has yet to happen remains to be seen, as several unknowns are still part of the equation.
“I think it is extremely likely that a subsurface ammonia-rich ocean exists in Triton,” said Saswata Hier-Majumder at the University of Maryland’s Department of Geology, whose team’s paper was recently published in the August edition of the journal Icarus. “[Yet] there are a number of uncertainties in our knowledge of Triton’s interior and past which makes it difficult to predict with absolute certainty.”
