Condensed-Matter Physics: Multitasking Materials from Atomic Templates

Date Published	09/2017
Publication Type	Journal Article

Author	Manfred Fiebig
DOI	10.1038/537499a
Abstract	Two 'failed' materials can perform much better when united. Such a combination exhibits magnetization and electric polarization up to room temperature, providing a basis for new magnetoelectric devices. See Letter p.523 Materials in which the electric dipoles or magnetic moments associated with atoms, ions or molecules are ordered are of immense technological value. Multiferroic materials unite these two types of order in a single material and are therefore highly desirable. However, because simultaneous electric and magnetic order is difficult to achieve, multiferroics — especially those that function at or approaching room temperature — are extremely rare. On page 523, Mundy et al. detail an effort to build such a material. Remarkably, they achieved this by combining two 'failed' multiferroics, forming a new compound with excellent multiferroic properties.
Notes	Associated Content Atomically Engineered Ferroic Layers Yield a Room-Temperature Magnetoelectric Multiferroic 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 Nature 537, 523–527 (22 September 2016) doi:10.1038/nature19343
Journal	Nature
Volume	537
Year of Publication	2016
Issue	7621
Pagination	499 - 500
Type of Article	News & Views
ISSN Number	0028-0836
Short Title	Nature
Keywords	Materials science Condensed matter physics
Research Areas	Ramesh Lab
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