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Experiments at the U.S. Department of Energy's Brookhaven National Laboratory shed new light on some materials' ability to dramatically change their electrical resistance in the presence of an external magnetic or electric field. Small changes in resistance underlie many electronic devices, including some computer data storage systems. Understanding and applying dramatic resistance changes, known as colossal magnetoresistance, offers tremendous opportunities for the development of new technologies, including data-storage devices with increased data density and reduced power requirements.
"This is an extremely important piece of work with broad potential application in developing the next generation of electronic and data-storage devices," said Brookhaven physicist Yimei Zhu, one of the lead authors on a paper appearing in the August 21, 2007 Proceedings of the National Academy of Sciences, now available online.
The Brookhaven scientists were studying crystalline perovskite manganites that had been doped with extra charge carriers - electrons or "holes" (the absence of electrons) - using various state-of-the-art electron microscopy techniques. In an unprecedented experiment, the scientists used a scanning-tunneling microscope that was built inside an electron microscope to apply an electric stimulus to the sample while observing its response at the atomic scale.
Using this technique, the scientists obtained, for the first time, direct evidence that a small electric stimulus can distort the shape of the crystal lattice, and also cause changes in the way charges travel through the lattice. The lattice distortions accompanied the charge carrier as it moved through the lattice, producing a particle-like excitation called a polaron. "Polarons can be pictured as a charge carrier surrounded by a 'cloth' of the accompanying lattice vibrations," Zhu said.
Zhu's group observed polarons melting and reordering - that is, undergoing a transition from solid to liquid to solid again - in response to the applied current, which the scientists have identified as the key mechanism for colossal mangetoresistance. The technique also allowed the scientists to study polaron behavior, i.e., how variations in electric field, current, and temperature affected this transition.
We show that static long-range ordering of polarons forms a polaron solid, which represents a new type of charge and orbital ordered state," said Zhu. "The related lattice distortions connect this phenomenon to colossal resistance effects, and suggest ways of modifying charge density and electronic interactions at the vicinity of electric interfaces and electrodes."
Colossal resistance effects could result in miniaturization of electric circuits that operate at lower power. This work therefore has direct impact on the application of these materials in the development of new electronic and spintronic devices (devices that use 'a combination of electron spin and charge). Such devices include new forms of "nonvolatile" computer memory (memory that can retain stored information even when not powered) such as resistive random access memory (RRAM).
 

About The Researchers:

Dr. Yimei Zhu
Senior Scientist, Center for Functional Nanomaterials, Brookhaven National Lab
Adjunct professor, Columbia University and Stony Brook University
Phone: (631)344-3057
Fax: (631)344-4071
E-Mail: zhu@bnl.gov
Dr. Zhu's wide research interests cover solid-state physics; nanoscale materials science and engineering; electronic structure and superconductivity; magnetic structure and magnetism; electron-beam scattering and its interaction with matter; synchrotron x-ray and neutron scattering; structural defects and interfaces in perovskites and transition-metal oxides; and, structural modeling and density functional theory calculations. Experimental research experience includes film growth; nanopatterning and lithography; quantitative analysis of intensity and phase of electron diffraction; atomic imaging; electron energy-loss spectroscopy; electron holography; in-situ magnetization and Lorentz microscopy; x-ray and neutron diffraction; and x-ray spectroscopy (XANES and EXAFS).
 

PD Dr. Christian Jooss
Institute fr Material physics
Friedrich-Hund-Platz 1
D-37077 Göttingen
Tel.: +49 551 39-5303
Fax: +49 551 39-5000
email: jooss
Room: D03.119
High-temperature superconducting films: Development of an understanding of the current transport in HTS on all length scales. Main topics are properties of grain boundaries, vortex pinning, vortex dynamics and the behavior of superconductors in magnetic environments.
Charge ordered manganate films: Study of the metal insulator transition, electronic phase separation and magnetic properties. Tailoring of the MI transition by controlling the defect formation and sample dimensions on the nanoscale. This work is part of the SFB 602.
Ferromagnetic thin films: Growth and patterning of hard and soft magnetic thin films. Development of a full quantitative spatial imaging of magnetization distributions. Realisation of nanopatterned hard magnetic films.

Funded:

This work was done in collaboration with Christian Jooss, a Brookhaven visiting scientist, and colleagues from the University of Goettingen, Germany. The work was funded by the Office of Basic Energy Sciences within the U.S. Department of Energy's Office of Science and by the German Research Foundation
In The Images-
1.The method: Scientists used an electron probe (green) to make images and collect other data while using a scanning tunneling microscope tip (red) to apply current or an electric field to the sample. The first layered image of black lines shows polaron waves, which propagate during the application of the current. Fine dots in the second layer are the individual atoms, while the periodic dot-clusters show the electron ordered state. The graph of electron energy loss spectroscopy (EELS) reveals bonding-electron excitation. The bottom layer is a structural model of the crystal lattice. And the vertical graph shows the electric resistance (I-V curve) of the crystal when current is applied.
2.Experiments at Brookhaven shed new light on some materials'
3.The crystal lattice: A structural model showing disordered (A) and polaron ordered (B) states during application of electric stimulus. The models reveal details of the experimental results including atomic position, lattice displacement, electron polarization (p), and magnetic spin direction (m). For more explanation, see the PNAS paper