Mineralogists of the Universities Jena and Bayreuth explain in the
science magazine Nature Geoscience why plate tectonics stagnates in some
places
The Earth is dynamic. What we perceive as solid ground beneath our
feet, is in reality constantly changing. In the space of a year Africa
and America are drifting apart at the back of the Middle Atlantic for
some centimeters while the floor of the Pacific Ocean is subducted
underneath the South American Continent.
Credit: Wikipedia
The Earth is the only planet in our solar system, conducting such a 'facelift' on a regular basis. But the continuous up and down on the Earth`s crust doesn't run smoothly everywhere. "Seismic measurements show that in some mantle regions, where one slab is subducted underneath another one, the movement stagnates, as soon as the rocks have reached a certain depth," says Prof. Langenhorst. The causes of the 'congestion' of the subducted plate are still unknown. In the current issue of the science magazine 'Nature Geoscience' Prof. Langenhorst and earth scientists of Bayreuth University now explain the phenomenon for the first time (DOI: 10.1038/NGEO1772).
According to this, the rocks of the submerging ocean plate pond at a depth of 440 to 650 kilometers – in the transition zone between the upper and the lower Earth mantle. "The reason for that can be found in the slow diffusion and transformation of mineral components," mineralogist Langenhorst explains.
"In 100 million years' time Africa will be pulled apart and North
Australia will be at the equator," says Prof. Dr. Falko Langenhorst from
the Friedrich Schiller University Jena (Germany). Plate tectonics is
leading to a permanent renewal of the ocean floors, the mineralogist
explains. The gaps between the drifting slabs are being filled up by
rising melt, solidifying to new oceanic crust. In other regions the
slabs dive into the deep interior of the Earth and mix with the
surrounding Earth's mantle.
Credit: Wikipedia
The Earth is the only planet in our solar system, conducting such a 'facelift' on a regular basis. But the continuous up and down on the Earth`s crust doesn't run smoothly everywhere. "Seismic measurements show that in some mantle regions, where one slab is subducted underneath another one, the movement stagnates, as soon as the rocks have reached a certain depth," says Prof. Langenhorst. The causes of the 'congestion' of the subducted plate are still unknown. In the current issue of the science magazine 'Nature Geoscience' Prof. Langenhorst and earth scientists of Bayreuth University now explain the phenomenon for the first time (DOI: 10.1038/NGEO1772).
According to this, the rocks of the submerging ocean plate pond at a depth of 440 to 650 kilometers – in the transition zone between the upper and the lower Earth mantle. "The reason for that can be found in the slow diffusion and transformation of mineral components," mineralogist Langenhorst explains.
On the basis of high pressure experiments the scientists were able to
clarify things: under the given pressure and temperature in this depth,
the exchange of elements between the main minerals of the subducted
ocean plate – pyroxene and garnet – is slowed down to an extreme extent.
"The diffusion of a pyroxene-component in garnet is so slow, that the
submerging rocks don't become denser and heavier, and therefore
stagnate," the Jena scientist says.
Interestingly there is congestion in the earth mantle exactly where the ocean floor submerges particularly fast into the interior of the Earth. "In the Tonga rift off Japan for example, the speed of subduction is very high," Prof. Langenhorst states. Thereby the submerging rocks of the oceanic plate stay relatively cold up to great depth, which makes the exchange of elements between the mineral components exceptionally difficult.
Interestingly there is congestion in the earth mantle exactly where the ocean floor submerges particularly fast into the interior of the Earth. "In the Tonga rift off Japan for example, the speed of subduction is very high," Prof. Langenhorst states. Thereby the submerging rocks of the oceanic plate stay relatively cold up to great depth, which makes the exchange of elements between the mineral components exceptionally difficult.
"It takes about 100 Million years for pyroxene crystals which are
only 1 mm in size to diffuse into the garnet. For this amount of time
the submerging plate stagnates," Langenhorst describes the rock
congestion. It can probably only diffuse at the boundary of the lower
Earth mantle. Because then pyroxene changes into the mineral akimotoite
due to the higher pressure in the depth of 650 kilometers. "This could
lead to an immediate rise in the rock density and would enable the
submerging into greater depths."
Contacts and sources:
Ute Schoenfelder
Contacts and sources:
Ute Schoenfelder
Citation: Van Mierlo VL et al. Stagnation of subducting slabs in
the transition zone due to slow diffusion in the majoritic garnet.
Nature
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