Forces that shape these young oceanic plates have come into clearer focus through research conducted by scientists at the Woods Hole Oceanographic Institution, Brown University and the Japan Agency for Marine-Earth Science and Technology.

The research represents the first time that seismic and electromagnetic data were analyzed in tandem from 1995 Mantle Electromagnetic and Tomography, or MELT, Experiment.

MELT employed 51 ocean-bottom seismometers and 30 magnetotelluric receivers two miles under the sea to measure sound waves and magnetic fields along the East Pacific Rise, making it one of the largest marine geophysical experiments ever conducted.

In a paper published in Nature, the team notes that in rock down to a depth of about 60 kilometers below the ocean floor, electrical currents conduct poorly and sound waves travel rapidly. Deeper down, beyond 60 kilometers, there is a dramatic increase in electrical conductivity, and sound waves travel at their slowest.

A switch in seismic and electrical properties with depth was expected. Researchers were surprised, however, at how close to the East Pacific Rise this structure develops and how little it changes with increasing distance from the rise.

Brown marine geophysicist Donald Forsyth said the team, led by Robert Evans from the Woods Hole Oceanographic Institution, has a theory about the cause of the sudden compositional changes at 60 kilometers: dehydration.

As magma migrates to the surface to form crust at the rise, it leaves behind a dry, residual layer about 60 kilometers thick. This change from "dry" surface rock to "damp" rock below it increases electrical conductivity and slows seismic velocity, the researchers write.

Here is what they did not expect: These changes occur, the team found, less than 100 kilometers away from the highest point on the ridge. And the seismic and electrical measurements remained nearly constant at least about 500 kilometers away from the crest.

Separating seafloor guides magma up to mid-ocean ridges such as the East Pacific Rise, where the molten rock erupts, fans out along the ocean floor and cools to form new crust. Cooling allows sound waves and electrical currents to travel faster. But scientists thought this cooling � and the resulting changes in the rock � would be gradual.

"About two-thirds of the Earth's surface is oceanic crust � and it is all formed at ridges," Forsyth said. "So this work helps us better understand the basic processes of how this crust is formed."

The National Science Foundation funded MELT and the latest research.

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