Washington, September 17 : A team of researchers has discovered that materials deep inside Earth have unexpected atomic properties that might force earth scientists to revise their models of Earth's internal processes.
A team of scientists led by Jung-Fu Lin at The University of Texas at Austin's Jackson School of Geosciences recreated in the lab the materials, crushing pressures and infernal temperatures they believe exist in the lowermost mantle, nearly 2,900 kilometers (1,800 miles) below Earth's surface.
According to the researchers, the materials exhibit rare and unexpected atomic properties that might influence how heat is transferred within Earth's mantle, how columns of hot rock called superplumes form, and how the magnetic field and heat generated in Earth's core travel to the planet's surface.
The planetary building blocks magnesium, silicon, oxygen and iron are the most abundant minerals in the lowermost mantle.
Jung-Fu Lin and his team synthesized materials from these building blocks in a diamond anvil cell, a device containing two interlocking diamond pieces that squeeze the sample like a vice.
They subjected the sample to more than 1.3 million times standard atmospheric pressure.
Shining a laser through the transparent diamonds, they then heated the sample to almost 3,000 degrees Celsius (5,400 degrees Fahrenheit) for several days.
The scientists used a facility at Argonne National Laboratory called a synchrotron light source, to reveal the sample's electronic and atomic structure.
They determined that the high pressures had caused some of the electrons in the sample's iron, which normally repel each other, to "pair up" or become bound to each other.
This was the first evidence of a broad region in the subsurface with what scientists describe as "intermediate-spin state," or partially paired iron electrons.
"We were surprised to find partially paired electrons," said Lin. "That doesn't normally occur in other geological materials that we know about," he added.
The degree of electron pairing, also known as electronic spin state, can affect how well the materials conduct heat and electricity.
According to Lin, modelers who make computer simulations of mantle dynamics will now have to go back and try to determine how this intermediate-spin state might affect the way heat is transferred within Earth, how superplumes form, how convection occurs in the mantle and how Earth's magnetic field might radiate from the core.
The electronic spin state can also affect the speed of seismic waves traveling through material in the deep mantle.
As a result, seismic images of the lowermost mantle-collected when earthquake vibrations travel through and reflect off of material in the subsurface-may have to be reinterpreted.