New study links mantle flow to ‘uplift and volcanism in mobile belts’
By ANIThursday, June 3, 2010
London, June 3 (ANI): Mountains and volcanoes in the Mediterranean rise due to pressure from the mantle below, according to a new study.
The new theory appears in the journal Nature.
Study co-author Thorsten Becker of the University of Southern California, said: “The rise and subsidence of different points of the earth is not restricted to the exact locations of the plate boundary. You can get tectonic activity away from a plate boundary.”
The study connects mantle flow to uplift and volcanism in “mobile belts”: crustal fragments floating between continental plates.
The model should be able to predict uplift and likely volcanic hotspots in other mobile belts, such as the North American Cordillera (including the Rocky Mountains and Sierra Nevada) and the Himalayas.
Becker said: “We have a tool to be able to answer these questions.”
Scientists previously had suggested a connection between mantle upwelling and volcanism, Becker said.
This is the first study to propose the connection in mobile belts.
Becker and collaborator Claudio Faccenna of the University of Rome believe that small-scale convection in the mantle is partly responsible for shaping mobile belts.
Mantle that sinks at the plate boundary flows back up farther away, pushing on the crust and causing uplift and crustal motions detectable by global positioning system, the authors found.
The slow but inexorable motions can move mountains - both gradually and through earthquakes or eruptions.
The study identified two mountain ranges raised almost entirely by mantle flow, according to the authors: the southern Meseta Central plateau in Spain and the Massif Central in France.
Becker and Faccenna inferred mantle flow from interpreting seismic mantle tomography, which provides a picture of the deep earth just like a CAT scan, using seismic waves instead of X-rays.
Assuming that the speed of the waves depends mainly on the temperature of crust and mantle (waves travel slower through warmer matter), the authors used temperature differences to model the direction of mantle convection.
Regions of upward flow, as predicted by the model, mostly coincided with uplift or volcanic activity away from plate boundaries.
The authors write: “Mantle circulation … appears more important than previously thought, and generates vigorous upwellings even far from the subduction zone.” (ANI)