The discoveries resulting from
our increasing ability to manipulate atomic placement continue to impress. We are adding a whole range of extraordinary tools
that will allow increasingly complex three dimensional complexes to be
fabricated with unimaginable complexity of electronic and magnetic behavior.
I also think that we are
approaching the point in which we will need computer assisted creative design
methods to truly exploit this capability.
Recall the architecture of the brain to imagine were this is all going.
Again, this is counter intuitive
for folks with a basic understanding of the theory.
Rare Coupling of Magnetic and Electric Properties in a Single Material
by Staff Writers
Brookhaven physicists Stuart Wilkins (left) and John Hill at NSLS
beamline X1A2, where their research was performed with a new soft x-ray
scattering facility.
Researchers at the U.S.
The researchers, who worked with colleagues at the Leibniz Institute
for Solid State and Materials Research in Germany, published their findings
online in Physical Review Letters on July 25, 2011.
Ferromagnets are materials that display a permanent magnetic moment, or
magnetic direction, similar to how a compass needle always points north. They
assist in a variety of daily tasks, from sticking a reminder to the fridge door
to storing information on a computer's hard drive.
Ferroelectrics are materials that display a permanent electric
polarization - a set direction of charge - and respond to the application of an
electric field by switching this direction. They are commonly used in
applications like sonar, medical imaging, and sensors.
"In principle, the coupling of an ordered magnetic material with
an ordered electric material could lead to very useful devices," said
Brookhaven physicist Stuart Wilkins, one of the paper's authors.
"For instance, one could imagine a device in which information is
written by application of an electric field and read by detecting its magnetic
state. This would make a faster and much more energy-efficient data storage
device than is available today."
But multiferroics - magnetic materials with north and south poles that
can be reversed with an electric field - are rare in nature. Ferroelectricity
and magnetism tend to be mutually exclusive and interact weakly with each other
when they coexist.
Most models used by physicists to describe this coupling are based on
the idea of distorting the atomic arrangement, or crystal lattice, of a
magnetic material, which can result in an electric polarization.
Now, scientists have found a new way that electric and magnetic
properties can be coupled in a material. The group used extremely bright beams
of x-rays at Brookhaven's National Synchrotron Light Source (NSLS) to examine
the electronic structure of a particular metal oxide made of yttrium,
manganese, and oxygen. They determined that the magnetic-electric coupling is
caused by the outer cloud of electrons surrounding the atom.
"Previously, this mechanism had only been predicted theoretically
and its existence was hotly debated," Wilkins said.
In this particular material, the manganese and oxygen electrons mix
atomic orbitals in a process that creates atomic bonds and keeps the material
together.
The researchers' measurements show that this process is dependent upon
the magnetic structure of the material, which in this case, causes the material
to become ferroelectric, i.e. have an electric polarization. In other words,
any change in the material's magnetic structure will result in a change in
direction of its ferroelectric state. By definition, that makes the material a
multiferroic.
"What is especially exciting is that this result proves the
existence of a new coupling mechanism and provides a tool to study it,"
Wilkins said.
The researchers used a new instrument at NSLS designed to answer key
questions about many intriguing classes of materials such as multiferroics and
high-temperature superconductors, which conduct electricity without resistance.
The instrument, developed by Wilkins and Brookhaven engineers D. Scott
Coburn, William Leonhardt, and William Schoenig, will ultimately be moved to
the National Synchrotron Light Source II (NSLS-II), a state-of-the-art machine
currently under construction. NSLS-II will produce x-rays 10,000 times brighter
than at NSLS, enabling studies of materials' properties at even higher
resolution.
This work was supported by the U.S.
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