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Underlying connection found between diverse materials with extreme magnetoresistance

Unifying phase diagrams could be used to find materials with useful applications in magnetic memory

Date:
June 14, 2016
Source:
Princeton University
Summary:
Researchers studying the intersection of materials chemistry and physics have found a connection in the underlying physics of materials with extreme magnetoresistance, a property that could be very useful in magnetic memory.
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Resistance-temperature-applied-magnetic-field diagrams of materials exhibiting extreme magnetoresistance are shown.
Credit: Cava lab

A new study from the Cava lab has revealed a unifying connection between seemingly unrelated materials that exhibit extreme magnetoresistance, the ability of some materials to drastically change their electrical resistance in response to a magnetic field, a property that could be useful in magnetic memory applications.

"The chemistry of these materials looks completely different but they're connected on a profound level by their physics," said Robert Cava, the Russell Wellman Moore professor of chemistry and corresponding author on the work published in the Proceedings of the National Academy of Sciences.

Numerous materials with extreme magnetoresistance have been reported since the Cava lab first discovered extreme magnetoresistance (originally named 'large magnetoresistance' by Nature editors before the research field supplanted it with the current term) in WTe2 two years ago.

But in particular, researchers in the Cava lab noticed that five materials with extreme magnetoresistance yet very different structures and chemical make-up all share the same characteristics when their resistance-temperature-applied-magnetic-field diagrams are measured. This diagram maps the temperature and magnetic field strength at which the material's magnetoresistance turns on and then saturates. Using the phase diagrams as a clue, scientists may be able to identify other materials with extreme magnetoresistance.

Detailed investigations by Fazel Tafti, a former Cava lab postdoc and physics PhD, revealed a common feature related to the materials' electronic structures, leading the researchers to propose a picture of the underlying physics that unifies these chemically disparate materials. This kind of research, where materials chemistry and materials physics meet, is what the Cava lab and its collaborators enjoy the most, Cava said.

"Now we hope that other people will think about this, and make more measurements to see whether our proposal for the unifying physics holds up to more intense scrutiny," Cava said. He was confident that first author Fazel Tafti, now an assistant professor of physics at Boston College, would get to the bottom of this phenomenon. "Physicists quest for truth," he said.


Story Source:

Materials provided by Princeton University. Original written by Tien Nguyen. Note: Content may be edited for style and length.


Journal Reference:

  1. Fazel Fallah Tafti, Quinn Gibson, Satya Kushwaha, Jason W. Krizan, Neel Haldolaarachchige, Robert Joseph Cava. Temperature−field phase diagram of extreme magnetoresistance. Proceedings of the National Academy of Sciences, 2016; 201607319 DOI: 10.1073/pnas.1607319113

Cite This Page:

Princeton University. "Underlying connection found between diverse materials with extreme magnetoresistance: Unifying phase diagrams could be used to find materials with useful applications in magnetic memory." ScienceDaily. ScienceDaily, 14 June 2016. <www.sciencedaily.com/releases/2016/06/160614214421.htm>.
Princeton University. (2016, June 14). Underlying connection found between diverse materials with extreme magnetoresistance: Unifying phase diagrams could be used to find materials with useful applications in magnetic memory. ScienceDaily. Retrieved May 23, 2017 from www.sciencedaily.com/releases/2016/06/160614214421.htm
Princeton University. "Underlying connection found between diverse materials with extreme magnetoresistance: Unifying phase diagrams could be used to find materials with useful applications in magnetic memory." ScienceDaily. www.sciencedaily.com/releases/2016/06/160614214421.htm (accessed May 23, 2017).

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