新澳门六合彩内幕信息

This In Focus story is a part of the Driven by Curiosity series.

New Clues to Deep Earthquake Mystery

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Cross section of a subduction zone
Subduction zones occur where one tectonic plate dives under another. New computer modeling by Magali Billen, professor of earth and planetary sciences at 新澳门六合彩内幕信息 Davis, shows why earthquakes on these sinking plates cluster at certain depths and could give insight into processes deep in the Earth. (U.S. Geological Survey)

A new understanding of our planet鈥檚 deepest earthquakes could help unravel one of the most mysterious geophysical processes on Earth.

Deep earthquakes 鈥 those at least 300 kilometers below the surface 鈥 don鈥檛 typically cause damage, but they are often widely felt. These earthquakes can provide vital clues to understanding plate tectonics and the structure of the Earth鈥檚 interior. Due to the extremely high temperature and pressures where deep earthquakes occur, they likely stem from different physical and chemical processes than earthquakes near the surface. But it鈥檚 hard to gather information about deep earthquakes, so scientists don鈥檛 have a solid explanation for what causes them.

鈥淲e can鈥檛 directly see what鈥檚 happening where deep earthquakes occur,鈥 said Magali Billen, professor of geophysics in the University of California, Davis, .

What鈥檚 driving deep earthquakes?

Billen builds , where one plate sinks below another, to better understand the forces controlling plate tectonics. Her recent work helps explain the distribution of deep earthquakes, showing that they most often strike in regions of 鈥渉igh strain鈥 where a sinking tectonic plate bends and folds. 

Model of subducting plate
Model of subducting plate shows why earthquakes cluster at certain depths (Magali Billen)

鈥淭hese models provide compelling evidence that strain rate is an important factor in controlling where deep earthquakes occur,鈥 she said.

The new understanding that deformation is a major factor in deep earthquakes should help scientists resolve which mechanisms trigger deep earthquakes and can provide new constraints on subduction zone structure and dynamics, Billen said.

鈥淥nce we understand deep earthquake physics better, we will be able to extract even more information about the dynamics of subduction, the key driver of plate tectonics,鈥 she said.

Her findings were published May 27 in the journal .

New way to study deep earthquakes

Deep earthquakes occur in subduction zones 鈥 where one of the tectonic plates floating on the surface of the Earth dives under another and is 鈥渟ubducted鈥 into the mantle. Within the sinking slabs of crust, earthquakes cluster at some depths and are sparse in others. For example, many slabs exhibit large gaps in seismic activity below 410 kilometers in depth.

The gaps in seismicity line up with regions of the slab that are deforming more slowly in the numerical models, Billen said.

鈥淒eformation is not the same everywhere in the plate,鈥 Billen said. 鈥淭hat鈥檚 really what鈥檚 new here.鈥

Billen鈥檚 research was not originally intended to investigate deep earthquakes. Rather, she was trying to understand the slow, back-and-forth motion of deep ocean trenches, where plates bend downward in subduction zones.

鈥淚 decided out of curiosity to plot the deformation in the plate, and when I looked at the plot, the first thing that popped in my mind was 鈥榳ow, this looks like the distribution of deep earthquakes,鈥欌 she said. 鈥淚t was a total surprise.鈥

 

 

Mimicking the deep Earth

Billen鈥檚 model incorporates the latest data about phenomena such as the density of minerals, different layers in the sinking plate, and experimental observations of how rocks behave at high temperatures and pressures.

鈥淭his is the first model that really brings together the physical equations that describe the sinking of the plates and key physical properties of the rocks,鈥 Billen said.

The results cannot distinguish between possible causes for deep earthquakes. However, they do provide new ways to explore what causes them, Billen said.

鈥淭aking into account the added constraint of strain-rate should help to resolve which mechanisms are active in the subducting lithosphere, with the possibility that multiple mechanisms may be required,鈥 she said.

The project was supported by a fellowship from the Alexander von Humboldt Foundation and an award from the National Science Foundation. The supports the CitcomS software used for the numerical simulations.

 

Media Resources

Magali Billen, Earth and Planetary Sciences, 530-754-5696, mibillen@ucdavis.edu

Andy Fell, News and Media Relations, 530-752-4533, ahfell@ucdavis.edu

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