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BE Technique Reveals ‘Rayleigh Behaviors’
May 2010
SANTA BARBARA, Calif., May 21, 2010 — The revolutionary new band excitation (BE) technique, co-developed by Oak Ridge National Laboratory (ORNL) and Asylum Research, has provided clues to the origins of unique properties of materials, including spin and cluster glasses, phase-separated oxides, polycrystalline ferroelectrics and ferromagnets, that are rooted in their highly disordered structures.

Spatial maps of nonlinearity for different film thicknesses (thicknesses shown across top). The onset of nonlinearity with thickness proceeds through formation and merger of clearly visible micron-scale clusters with bulk nonlinearity value, as opposed to gradual increase of average nonlinearity.

These behaviors influence the scaling properties of the materials, including the thickness of thin films at which improved properties manifest. So-called "Rayleigh behaviors" have a direct bearing on the properties of nanoscale materials and, eventually, the uniformity of nanoscale devices.

The new observations, which were made possible by advances in scanning probe microscopy (SPM) at ORNL's Center for Nanophase Materials Sciences and Asylum Research, may result in the rethinking of 100-year-old theories behind the "quanta of nonlinearity" and properties of heterogeneous materials.

This work is funded by the Department of Energy’s Basic Energy Sciences CNMS user program. The principal investigators for this ground-breaking work are Stephen Jesse and Sergei Kalinin of ORNL, and Susan Trolier-McKinstry from Penn State. The findings were published April 20, 2010, in a Proceedings of the National Academy of Sciences (PNAS) article titled “Collective dynamics underpins Rayleigh behavior in disordered polycrystalline ferroelectrics.”

“The nonlinear responses are a ubiquitous aspect of disordered materials that is directly linked to their unique functional properties,” said Sergei Kalinin of ORNL. “Our studies illustrate that the emergence of the nonlinear behavior is associated with large-scale collective responses, providing new clues to century-old problems.”

"The amazing aspect of BE measurements is that the local nonlinearity is measured quantitatively with less than 10% absolute error in volumes millions of times smaller than those addressable by macroscopic measurements,” added Roger Proksch, president of Asylum Research. “This is highly unusual for SPM."

For more information, visit: 

AmericasAsylum Researchatomic force microscopyBand ExcitationBasic ScienceCaliforniadisordered materialsMicroscopynanonanomaterialsnanostructured materialsquanta of nonlinearityRayleigh behaviorResearch & TechnologyRoger Prokschscanning probe microscopySergei Kalinin

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