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Asylum’s Band Excitation Technique Grants Awarded

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SANTA BARBARA, Calif., March 29, 2010 — Asylum Research, manufacturer of scanning probe and atomic force (SPM/AFM) microscopes, has announced eight new grants for early adopters to explore the capabilities and applications of a new band excitation (BE) technique. The R&D100 Award-winning BE method is a fast and sensitive technique that allows mapping of conservative interactions, nonlinearities and energy dissipation of materials on the nanoscale, and shows great promise for understanding and mitigating energy losses in magnetic, electrical and electromechanical processes and technologies.

Grants valued at up to $50,000 each have been awarded to: 

    • Matt Dawber, Stony Brook University, “Accurate and advanced characterization of the piezoelectric figures of merit for tailored ferroelectric superlattices” 

    • Alexei Gruverman, University of Nebraska, “Band excitation scanning probe microscopy for nanoscale studies of bio-organic polymers” 

    • Brian Huey, University of Connecticut, “Band excitation methods for novel investigations of phase change materials and fuel cell systems” 

    • Jiangyu Li, University of Washington, “Band excitation for quantitative scanning probe microscopy of magnetoelastic coupling in galfenol” 

    • Lane Martin and Scott MacLaren, University of Illinois, Urbana-Champaign, “Band excitation studies of losses in local switching of modern ferroelectric and multiferroic thin films” 

    • Gunter Moeller and George Papakonstantopoulos, Arkema Inc., “Band excitation AFM to develop a dynamic mechanical analysis method for polymers” 

    • Brian Rodriguez, University College of Dublin, “Decoupling elastic and electromechanical responses using band excitation scanning probe microscopy” 

    • Neil Thompson, Colin Grant and Nagatha Wijayathunga, University of Leeds, “Band excitation AFM of collageneous materials”

“We at Asylum Research, along with BE inventors Stephen Jesse and Sergei Kalinin at Oak Ridge National Laboratory (ORNL), are excited about the quality of the proposals submitted for our grant program. In particular, we are excited about the increase in application areas. BE was born to improve piezoresponse force microscopy, but has spread to very diverse areas from polymers, to biology and battery technology. We look forward to working closely with this excellent group of researchers to advance the BE technique and its applications,” said Roger Proksch, president of Asylum Research.

For more information, visit:
Mar 2010
The use of atoms, molecules and molecular-scale structures to enhance existing technology and develop new materials and devices. The goal of this technology is to manipulate atomic and molecular particles to create devices that are thousands of times smaller and faster than those of the current microtechnologies.
AFMAlexei GruvermanArkema Inc.Asylum Researchatomic force microscopyBand ExcitationBasic Sciencebio-organic polymersBrian HueyBrian RodriguezBusinessColin Grantcollagenconservative interactionsenergy dissipationfuel cellsgalfenolgrantsGunter Moeller and George PapakonstantopoulosimagingJiangyu LiLane Martinmaterialsmaterials researchMatt DawberMicroscopyNagatha WijayathungananosciencenanotechnologyNeil Thompsonnonlinearitiesopticspiezoelectricsscanning probe microscopyScott MacLarenSPMStony Brook Universitythin filmsUniversity College of DublinUniversity of ConnecticutUniversity of Illinois Urbana-ChampaignUniversity of LeedsUniversity of NebraskaUniversity of Washington

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