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Subducting oceanic plates are thinning adjacent continents 

HOUSTON – (Nov. 13, 2014) – The continental margins of plates on either side of the Atlantic Ocean are thinner than expected, and an international team led by a Rice University scientist is using an array of advanced tools to understand why.

According to Alan Levander, lead author of a new paper in Nature and the Carey Croneis Professor of Earth Science at Rice, the viscous bottom layers of the continental shelves beneath the Gibraltar arc and northeastern South America are literally being pulled off by adjacent subducting oceanic plates.

Removing the base of the continental margin can destabilize the plate further inland by creating topography on the base of the lithosphere, he said. The topography can trigger additional downwellings by setting up small-scale convection in the underlying asthenosphere. The space left by the sinking lithosphere is filled by rising asthenosphere. As it rises, the asthenosphere can undergo partial melting, which gives rise to surface volcanism.

Levander and his team saw evidence of “dripping” lithosphere in a previous study of the Colorado plateau, and he thinks these “secondary downwellings” are similar in nature and common. “We see similar downwelling under South America right now, and there’s evidence that there’s been downwelling under parts of North Africa,” Levander said.

The researchers believe the new findings reconcile a number of “sometimes mutually exclusive” tectonic models at two subduction zones. “What I find interesting is that these two National Science Foundation (NSF) Continental Dynamics projects are on opposite sides of the Atlantic and they both involve relatively small subduction zones,” he said. “But we see what we think are the same processes in each one.”

None of this can be observed directly, but modern seismic instruments deployed in both regions have contributed greatly to Earth scientists’ ability to view processes deep within the planet.

“Until recently, we didn’t have a good way to tell where the bottoms of the tectonic plates were. Only with the development of fairly dense, observatory-quality seismic networks like USArray and dense deployments of instruments elsewhere in the world have we been able to determine local variations in lithosphere thickness,” Levander said. Many seismology groups are now studying the lithosphere-asthenosphere boundary (the LAB) under the oceans and continents, he said.

The study used portable seismographs belonging to the NSF-funded IRIS/PASSCAL facility that were deployed for several years with instruments from Spain’s IberArray and Venezuela’s National Seismograph Network. From that data, geophysicists determined the topography of the LAB using techniques roughly similar to medical CAT scans and ultrasound images.

“People have had an idea where the base of the lithosphere is since the ’70s and ’80s, but only on a very large scale,” Levander said. “Even regional variations were poorly resolved by the seismic data available at the time. There weren’t enough instruments.”

Co-authors of the paper are Maximiliano Bezada, a former Rice Ph.D. student now on the faculty at the University of Minnesota; Fenglin Niu, a professor of Earth science at Rice with an appointment at the China University of Petroleum; Eugene Humphreys, a professor of geophysics at the University of Oregon; postdoctoral researcher Inmaculada Palomeras and graduate students Sally Thurner and Jeniffer Masy, all of Rice; Michael Schmitz of the Venezuelan Foundation for Seismological Research; Josep Gallart and Ramon Carbonell of the Institute of Earth Science Jaume Almera, Barcelona, Spain; and Meghan Miller of the University of Southern California, Los Angeles.

The NSF, the Venezuelan National Fund for Science, Technology and Innovation, the Spanish Ministry of Science and Innovation and the Alexander von Humboldt Foundation supported the research. The Rice researchers utilized the NSF-funded DAVinCi Visualization Laboratory, administered by Rice’s Ken Kennedy Institute for Information Technology.

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Read the paper at http://www.nature.com/nature/journal/v515/n7526/full/nature13878.html

Follow Rice News and Media Relations via Twitter @RiceUNews

Related Materials:

Alan Levander: http://terra.rice.edu/web/people/levander.html

Rice Department of Earth Science: http://earthscience.rice.edu

Images for download:

https://news2.rice.edu/files/2014/11/1117_LEVANDER-2-web.jpg

A study led by Rice University found that continental plates on either side of the Atlantic Ocean are thinning under the influence of subducting oceanic plates. By pulling lower lithospheric material from the continental plates, the oceanic plate allows aesthenospheric material to rise, triggering seismic activity and downwelling of further inland. (Credit: Bezada et al., Journal of Geophysical Research, 115, B12333)

https://news2.rice.edu/files/2014/11/1117_LEVANDER-3-web.jpg

Downwelling (arrows) of lithospheric material from the South American continental plate can be observed from seismic images made from teleseismic earthquakes. A dense network of seismic instruments revealed the “dripping” reported on both sides of the Atlantic by a Rice University-led team. (Credit: Alan Levander/Rice University)

https://news2.rice.edu/files/2014/11/1117_LEVANDER-4-web.jpg

A network of seismic instruments revealed downwelling of continental lithosphere under northern South America associated with the Atlantic plate (ATL, left), as reported in a Rice University-led study in Nature. (Credit: Alan Levander/Rice University)

https://news2.rice.edu/files/2014/11/1117_LEVANDER-5-web.jpg

A Rice University-led team of scientists observed downwelling of material from the European and African continental plates, the result of the destabilizing effects of the subducting Alboran (Mediterranean) oceanic plate. The team’s new work in Nature finds similar effects on either side of the Atlantic. (Credit: Alan Levander/Rice University)

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