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Engineers create room-temperature multiferroic material

Date:
September 23, 2016
Source:
Cornell University
Summary:
Multiferroics -- materials that exhibit both magnetic and electric order -- are of interest for next-generation computing but difficult to create because the conditions conducive to each of those states are usually mutually exclusive. And in most multiferroics found to date, their respective properties emerge only at extremely low temperatures. Now researchers have combined two non-multiferroic materials, using the best attributes of both to create a new room-temperature multiferroic.
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Multiferroics -- materials that exhibit both magnetic and electric order -- are of interest for next-generation computing but difficult to create because the conditions conducive to each of those states are usually mutually exclusive. And in most multiferroics found to date, their respective properties emerge only at extremely low temperatures.

Two years ago, researchers in the labs of Darrell Schlom, the Herbert Fisk Johnson Professor of Industrial Chemistry in the Department of Materials Science and Engineering, and Dan Ralph, the F.R. Newman Professor in the College of Arts and Sciences, in collaboration with professor Ramamoorthy Ramesh at UC Berkeley, published a paper announcing a breakthrough in multiferroics involving the only known material in which magnetism can be controlled by applying an electric field at room temperature: the multiferroic bismuth ferrite.

Schlom's group has partnered with David Muller and Craig Fennie, professors of applied and engineering physics, to take that research a step further: The researchers have combined two non-multiferroic materials, using the best attributes of both to create a new room-temperature multiferroic.

Their paper, "Atomically engineered ferroic layers yield a room-temperature magnetoelectric multiferroic," was published -- along with a companion News & Views piece -- Sept. 22 in Nature. The lead authors are Julia Mundy, Ph.D. '14, a former doctoral student working jointly with Muller and Schlom who's now a postdoctoral researcher at the University of California, Berkeley; Charles Brooks, Ph.D., a visiting scientist in the Schlom group; and Megan Holtz, a doctoral student in the Muller group.

The group engineered thin films of hexagonal lutetium iron oxide (LuFeO3), a material known to be a robust ferroelectric but not strongly magnetic. The LuFeO3 consists of alternating single monolayers of lutetium oxide and iron oxide, and differs from a strong ferrimagnetic oxide (LuFe2O4), which consists of alternating monolayers of lutetium oxide with double monolayers of iron oxide.

The researchers found, however, that they could combine these two materials at the atomic-scale to create a new compound that was not only multiferroic but had better properties that either of the individual constituents. In particular, they found they need to add just one extra monolayer of iron oxide to every 10 atomic repeats of the LuFeO3 to dramatically change the properties of the system.

That precision engineering was done via molecular-beam epitaxy (MBE), a specialty of the Schlom lab. A technique Schlom likens to "atomic spray painting," MBE let the researchers design and assemble the two different materials in layers, a single atom at a time.

The combination of the two materials produced a strongly ferrimagnetic layer near room temperature. They then tested the new material at the Lawrence Berkeley National Laboratory (LBNL) Advanced Light Source in collaboration with co-author Ramesh to show that the ferrimagnetic atoms followed the alignment of their ferroelectric neighbors when switched by an electric field.

"It was when our collaborators at LBNL demonstrated electrical control of magnetism in the material that we made that things got super exciting," Schlom said. "Room-temperature multiferroics are exceedingly rare and only multiferroics that enable electrical control of magnetism are relevant to applications."

In electronics devices, the advantages of multiferroics include their reversible polarization in response to low-power electric fields -- as opposed to heat-generating and power-sapping electrical currents -- and their ability to hold their polarized state without the need for continuous power. High-performance memory chips make use of ferroelectric or ferromagnetic materials.

"Our work shows that an entirely different mechanism is active in this new material," Schlom said, "giving us hope for even better -- higher-temperature and stronger -- multiferroics for the future."


Story Source:

Materials provided by Cornell University. Original written by Tom Fleischman. Note: Content may be edited for style and length.


Journal References:

  1. Julia A. Mundy, Charles M. Brooks, Megan E. Holtz, Jarrett A. Moyer, Hena Das, Alejandro F. Rébola, John T. Heron, James D. Clarkson, Steven M. Disseler, Zhiqi Liu, Alan Farhan, Rainer Held, Robert Hovden, Elliot Padgett, Qingyun Mao, Hanjong Paik, Rajiv Misra, Lena F. Kourkoutis, Elke Arenholz, Andreas Scholl, Julie A. Borchers, William D. Ratcliff, Ramamoorthy Ramesh, Craig J. Fennie, Peter Schiffer, David A. Muller, Darrell G. Schlom. Atomically engineered ferroic layers yield a room-temperature magnetoelectric multiferroic. Nature, 2016; 537 (7621): 523 DOI: 10.1038/nature19343
  2. Manfred Fiebig. Condensed-matter physics: Multitasking materials from atomic templates. Nature, 2016; 537 (7621): 499 DOI: 10.1038/537499a

Cite This Page:

Cornell University. "Engineers create room-temperature multiferroic material." ScienceDaily. ScienceDaily, 23 September 2016. <www.sciencedaily.com/releases/2016/09/160923122217.htm>.
Cornell University. (2016, September 23). Engineers create room-temperature multiferroic material. ScienceDaily. Retrieved December 21, 2024 from www.sciencedaily.com/releases/2016/09/160923122217.htm
Cornell University. "Engineers create room-temperature multiferroic material." ScienceDaily. www.sciencedaily.com/releases/2016/09/160923122217.htm (accessed December 21, 2024).

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