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MIT physicists have discovered that several high-temperature superconductors display patchwork quilt-like variations at the atomic scale, a surprising finding that could help scientists understand a new class of unconventional materials.

The researchers said the variation in a property known as the Fermi surface, which has never been seen before in any kind of material, could just be an oddity. But it could also serve as an important clue for physicists working to unravel the mystery of why a broad new class of materials exhibits exotic properties from high-temperature superconductivity (the ability to carry electricity with no resistance) to colossal magneto-resistance (the ability to dramatically change electrical resistance when a magnetic field is applied).

In such materials, known as strongly correlated electronic materials, interactions between electrons, normally weak enough that they can essentially be ignored, dominate the physics of the material, leading to a host of unexplained phenomena.

"These materials are so unusual that we decided to check for variations that would normally be impossible -- and there they were," said Eric Hudson, associate professor of physics and senior author of a paper on the work that appeared online in Nature Physics Jan. 25.

Hudson and colleagues found that the Fermi surface, a measurement of the distribution of electrons in a material, varies at the atomic scale across the surface of two bismuth-based superconductors, which belong to the class of strongly correlated electronic materials. Until now, it was believed that Fermi surface was uniform throughout any material.

"The idea that electrons separated by just an atom's distance can behave so differently is astonishing," Hudson said.

The discovery that electronic properties can vary so much on the nanoscale could shed light on how this class of materials deals with strongly interacting electrons, and how their unusual properties arise, he said.

To study the Fermi surface, the researchers used a common technique called scanning tunneling microscopy, which, combined with a new analysis method called quasiparticle interference, can reveal, on an atom-by-atom basis, what electrons are doing.

Lead author of the paper is physics graduate student William Wise. Other MIT authors are graduate student Kamalesh Chatterjee; former graduate student Michael Boyer; and former postdoctoral associates Takeshi Kondo and Yayu Wang. Researchers from Nagoya University in Japan and Brookhaven National Laboratory also contributed to the work.

This research was funded by the Research Corporation, the Materials Research Science and Engineering Center, National Science Foundation and Department of Energy.

About The Researcher :

ERIC W. HUDSON,

Associate Professor of Physics

Research Interests:

Professor Hudson's main interests lie in nanoscale investigations of strongly correlated electron systems, such as high temperature superconductors (HTSC). In particular, he is interested in the fundamental question of how defects and disorder affect these systems, as well as the more practical question of what observations about these effects at the microscopic level can tell us about the macroscopic nature of these systems.

Biographical Sketch:

Professor Eric Hudson joined the Department of Physics as an Assistant Professor in January 2002. He received a B.A. in Physics/Linguistics in 1992 from the University of Chicago, and completed his Ph.D. at the University of California, Berkeley, in 1999. After a brief postdoctoral tenure at UC-Berkeley, continuing his research on scanning tunneling microscopy (STM) of impurities and disorder in superconductors, he became an NRC Postdoctoral Research Associate in the Electron Physics Group at the National Institute of Standards and Technology (NIST), studying spin polarized STM.

Contact Information :

Email: ehudson@mit.edu

Phone:
     Office: (617) 452-2115
     Lab: (617) 253-2012

Address:
     Office: 13-2154
     Lab: 24-038