An analysis of gravity and
topography(地势) data from
Saturn1's largest moon, Titan, has revealed unexpected features of the moon's outer ice shell. The best explanation for the findings, the authors said, is that Titan's ice shell is
rigid2 and that
relatively3 small topographic features on the surface are associated with large roots extending into the
underlying4 ocean. The study is published in the August 29 issue of the journal Nature. Led by planetary scientists Douglas Hemingway and Francis Nimmo at the University of California, Santa Cruz, the study used new data from NASA's Cassini spacecraft. The researchers were surprised to find a negative
correlation5 between the gravity and topography signals on Titan.
"Normally, if you fly over a mountain, you expect to see an increase in gravity due to the extra mass of the mountain. On Titan, when you fly over a mountain the gravity gets lower. That's a very odd observation," said Nimmo, a professor of Earth and planetary sciences at UC Santa Cruz.
To explain that observation, the researchers developed a model in which each bump in the topography on the surface of Titan is
offset6 by a deeper "root" big enough to overwhelm the gravitational effect of the bump on the surface. The root is like an
iceberg7 extending below the ice shell into the ocean
underneath8 it. "Because ice is lower
density9 than water, you get less gravity when you have a big
chunk10 of ice there than when you have water," Nimmo explained.
An iceberg floating in water is
in equilibrium11(处于平衡状态), its
buoyancy(浮力,轻快) balancing out its weight. In this model of Titan, however, the roots extending below the ice sheet are so much bigger than the bumps on the surface that their buoyancy is pushing them up against the ice sheet. "It's like a big beach ball under the ice sheet pushing up on it, and the only way to keep it submerged is if the ice sheet is strong," said Hemingway, a doctoral candidate in planetary geophysics at UCSC and lead author of the paper. "If large roots are the reason for the negative correlation, it means that Titan's ice shell must have a very thick rigid layer."
The researchers calculated that, in this model, Titan's ice shell would have to have a rigid layer at least 40 kilometers thick. They also found that hundreds of meters of surface erosion and
deposition12 are needed to account for the observed imbalance between the large roots and small surface topography. The results from their model are similar to estimates obtained by geomorphologists studying the erosion of impact
craters13 and other features on Titan.
These findings have several implications. For example, a thick rigid ice shell makes it very difficult to produce ice volcanoes, which some have proposed to explain certain features seen on the surface.
Unlike Earth's geologically active crust, Titan's ice shell isn't getting recycled by convection or plate tectonics. "It's just sitting there, and weather and erosion are
acting14 on it, moving stuff around and redepositing sediments," Nimmo said. "It may be like the surface of Earth would be if you turned plate tectonics off."
The researchers are not sure what could have given rise to Titan's topographical features with their deep roots. Titan's eccentric orbit around Saturn generates tides that
flex15 the moon's surface and create tidal heating, which could cause variations to develop in the thickness of the ice shell, Hemingway said.
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