Scientists
Discover New Type of Magnet
A team of scientists has discovered the first robust example of a new type of magnet—one that holds promise for enhancing the performance of data storage technologies.
New York
A team of scientists has discovered the first robust example of a new type of magnet—one that holds promise for enhancing the performance of data storage technologies.
This “singlet-based” magnet differs from conventional
magnets, in which small magnetic constituents align with one another to create
a strong magnetic field. By contrast, the newly uncovered singlet-based magnet
has fields that pop in and out of existence, resulting in an unstable force—but
also one that potentially has more flexibility than conventional counterparts.
“There’s a great deal of research these days into the use
of magnets and magnetism to improve data storage technologies,” explains Andrew
Wray, an assistant professor of physics at New York University
“There's also a big difference in how this kind of
magnetism couples with electric currents. Electrons coming into the material
interact very strongly with the unstable magnetic moments, rather than simply
passing through. Therefore, it’s possible that these characteristics can help
with performance bottlenecks and allow better control of magnetically stored
information.”
The work,
published in the journal Nature Communications, also included
researchers from Lawrence Berkeley National Laboratory, the National Institute
of Standards and Technology, the University
of Maryland , Rutgers
University , the Brookhaven National
Laboratory, Binghamton
University
The idea for this type of magnet dates back to the 1960s,
based on a theory that stood in sharp contrast to what had long been known
about conventional magnets.
A typical magnet contains a host of tiny “magnetic
moments” that are locked into alignment with other magnetic moments, all acting
in unison to create a magnetic field. Exposing this assembly to heat will
eliminate the magnetism; these little moments will remain—but they’ll be
pointing in random directions, no longer aligned.
A pioneering thought 50 years ago, by contrast, posited
that a material that lacks magnetic moments might still be able to be a magnet.
This sounds impossible, the scientists note, but it works because of a kind of
temporary magnetic moment called a “spin exciton,” which can appear when
electrons collide with one another under the right conditions.
“A single spin exciton tends to disappear in short order,
but when you have a lot of them, the theory suggested that they can stabilize
each other and catalyze the appearance of even more spin excitons, in a kind of
cascade,” Wray explains.
In the Nature Communications research,
the scientists sought to uncover this phenomenon. Several candidates had been
found dating back to the 1970s, but all were difficult to study, with magnetism
only stable at extremely low temperatures.
Using neutron scattering, X-ray scattering, and theoretical
simulations, the researchers established a link between the behaviors of a far
more robust magnet, USb2, and the theorized characteristics of
singlet-based magnets.
“This material had been quite an enigma for the last
couple of decades—the ways that magnetism and electricity talk to one another
inside it were known to be bizarre and only begin to make sense with this new
classification,” remarks Lin Miao, an NYU postdoctoral fellow and the paper’s
first author.
Specifically, they found that USb2 holds
the critical ingredients for this type of magnetism—particularly a quantum
mechanical property called “Hundness” that governs how electrons generate
magnetic moments. Hundness has recently been shown to be a crucial factor for a
range of quantum mechanical properties, including superconductivity.
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