NIST's Neutron Facilities Reveal Intriguing Similarities that May Unlock Energy, Environmental Benefits
These superconductors may one day enable energy and environmental gains because they could significantly heighten the efficiency of transferring electricity over the electric grid or storing electricity in off-peak hours for later use.
"While we still do not understand how magnetism and superconductivity are related in copper-oxide superconductors," explains NIST Fellow Jeffrey Lynn at the NIST Center for Neutron Research (NCNR), "our measurements show that the new iron-based materials share what seems to be a critical interplay between magnetism and superconductivity."
The importance of magnetism to high-temperature superconductors is remarkable because magnetism strongly interferes with conventional low-temperature superconductors. "Only a few magnetic impurities in the low-temperature superconductors sap the superconducting properties away," says Lynn.
By contrast, copper-oxide superconductors, discovered in 1986, tolerate higher magnetic fields at higher temperatures. The highest performance copper-oxide superconductors conduct electricity without resistance when cooled to "transition temperatures" below 140 Kelvin (-133 Celsius) and can simply and cheaply be cooled by liquid nitrogen to 77 Kelvin (-196 Celsius).
Japanese researchers discovered earlier this year that a new class of iron-based superconducting materials also had much higher transition temperatures than the conventional low-temperature superconductors. The discovery sent physicists and materials scientists into a renewed frenzy of activity reminiscent of the excitement brought on by the discovery of the first high-temperature superconductors over 20 years ago.
Earlier work on the copper-oxide superconductors revealed that they consist of magnetically active copper-oxygen layers, separated by layers of non-magnetic materials. By "doping," or adding different elements to the non-magnetic layers of this normally insulating material, researchers can manipulate the magnetism to achieve electrical conduction and then superconductivity.
As neutrons probed an iron-based sample supplied by materials scientists in Beijing, they revealed a magnetism that is similar to that found in copper-oxide superconductors, that is, layers of magnetic moments—like many individual bar magnets—interspersed with layers of nonmagnetic material. Lynn notes that the layered atomic structure of the iron-based systems, like the copper-oxide materials, makes it unlikely that these similarities are an accident.
One of the exciting aspects of these new superconductors is that they belong to a comprehensive class of materials where many chemical substitutions are possible. This versatility is already opening up new research avenues to understand the origin of the superconductivity, and should also enable the superconducting properties to be tailored for commercial technologies.
Researchers from the following institutions partnered with NIST in these studies: University of Tennessee, Knoxville; Oak Ridge National Laboratory; University of Maryland; Ames Laboratory; Iowa State University and the Chinese Academy of Sciences' Beijing National Laboratory for Condensed Matter Physics.
*C. de la Cruz, Q. Huang, J.W. Lynn, J. Li, W. Ratcliff II, J.L. Zarestky, H.A. Mook, G.F. Chen, J.L. Luo, N.L. Wang and P. Dai. Magnetic order close to superconductivity in the iron-based layered La(O1-xFx)FeAs systems. Nature Advanced Online Publication, May 28, 2008.