If the icy surface of
Pluto1's giant moon Charon is cracked, analysis of the fractures could reveal if its interior was warm, perhaps warm enough to have maintained a
subterranean2(地下的,秘密的) ocean of liquid water, according to a new NASA-funded study. Pluto is an extremely distant world, orbiting the sun more than 29 times farther than Earth. With a surface temperature estimated to be about 380 degrees below zero
Fahrenheit3 (around minus 229 degrees Celsius), the environment at Pluto is far too cold to allow liquid water on its surface. Pluto's moons are in the same
frigid4 environment.
Pluto's remoteness and small size make it difficult to observe, but in July of 2015, NASA's New Horizons spacecraft will be the first to visit Pluto and Charon, and will provide the most
detailed5 observations to date.
"Our model predicts different fracture patterns on the surface of Charon depending on the thickness of its surface ice, the structure of the moon's interior and how easily it
deforms6, and how its orbit evolved," said Alyssa Rhoden of NASA's Goddard Space Flight Center in Greenbelt, Maryland. "By comparing the actual New Horizons observations of Charon to the various predictions, we can see what fits best and discover if Charon could have had a subsurface ocean in its past, driven by high
eccentricity7(古怪,离心率)." Rhoden is lead author of a paper on this research now available online in the journal Icarus.
Some moons around the gas giant planets in the outer solar system have cracked surfaces with evidence for ocean interiors -- Jupiter's moon Europa and Saturn's moon Enceladus are two examples.
As Europa and Enceladus move in their orbits, a gravitational tug-of-war between their respective parent planets and neighboring moons keeps their orbits from becoming circular. Instead, these moons have eccentric (slightly oval-shaped) orbits, which raise daily tides that
flex8 the interior and stress the surface. It is thought that tidal heating has extended the lifetimes of subsurface oceans on Europa and Enceladus by keeping their interiors warm.
In Charon's case, this study finds that a past high eccentricity could have generated large tides, causing
friction9 and surface fractures. The moon is unusually massive compared to its planet, about one-eighth of Pluto's mass, a solar system record. It is thought to have formed much closer to Pluto, after a giant impact ejected material off the planet's surface. The material went into orbit around Pluto and
coalesced10 under its own gravity to form Charon and several smaller moons.
Initially11, there would have been strong tides on both worlds as gravity between Pluto and Charon caused their surfaces to
bulge12(膨胀) toward each other, generating friction in their interiors. This friction would have also caused the tides to slightly lag behind their orbital positions. The lag would act like a brake on Pluto, causing its
rotation13 to slow while transferring that
rotational14 energy to Charon, making it speed up and move farther away from Pluto.
"Depending on exactly how Charon's orbit evolved, particularly if it went through a high-eccentricity phase, there may have been enough heat from tidal
deformation15 to maintain liquid water beneath the surface of Charon for some time," said Rhoden. "Using
plausible16 interior structure models that include an ocean, we found it wouldn't have taken much eccentricity (less than 0.01) to generate surface fractures like we are seeing on Europa."
"Since it's so easy to get fractures, if we get to Charon and there are none, it puts a very strong
constraint17 on how high the eccentricity could have been and how warm the interior ever could have been," adds Rhoden. "This research gives us a head start on the New Horizons arrival -- what should we look for and what can we learn from it. We're going to Pluto and Pluto is fascinating, but Charon is also going to be fascinating."