Electric field effects in RUS measurements

Much of the power of the Resonant Ultrasound Spectroscopy (RUS) technique is the ability to make mechanical resonance measurements while the environment of the sample is changed. Temperature and magnetic field are important examples. Due to the common use of piezoelectric transducers near the sample...

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Veröffentlicht in:	Ultrasonics 2010-02, Vol.50 (2), p.145-149
Hauptverfasser:	Darling, Timothy W., Allured, Bradley, Tencate, James A., Carpenter, Michael A.
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Sprache:	eng
Schlagworte:	Acoustical measurements and instrumentation Acoustics Cross-disciplinary physics: materials science rheology Dielectric Elasticity Electric fields Exact sciences and technology Fundamental areas of phenomenology (including applications) Materials science Materials testing Physics Polycrystals Quartzite Resonances Surface waves Transduction acoustical devices for the generation and reproduction of sound
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creator	Darling, Timothy W. Allured, Bradley Tencate, James A. Carpenter, Michael A.
description	Much of the power of the Resonant Ultrasound Spectroscopy (RUS) technique is the ability to make mechanical resonance measurements while the environment of the sample is changed. Temperature and magnetic field are important examples. Due to the common use of piezoelectric transducers near the sample, applied electric fields introduce complications, but many materials have technologically interesting responses to applied static and RF electric fields. Non-contact optical, buffered, or shielded transducers permit the application of charge and externally applied electric fields while making RUS measurements. For conducting samples, in vacuum, charging produces a small negative pressure in the volume of the material – a state rarely explored. At very high charges we influence the electron density near the surface so the propagation of surface waves and their resonances may give us a handle on the relationship of electron density to bond strength and elasticity. Our preliminary results indicate a charge sign dependent effect, but we are studying a number of possible other effects induced by charging. In dielectric materials, external electric fields influence the strain response, particularly in ferroelectrics. Experiments to study this connection at phase transformations are planned. The fact that many geological samples contain single crystal quartz suggests a possible use of the piezoelectric response to drive vibrations using applied RF fields. In polycrystals, averaging of strains in randomly oriented crystals implies using the “statistical residual” strain as the drive. The ability to excite vibrations in quartzite polycrystals and arenites is explored. We present results of experimental and theoretical approaches to electric field effects using RUS methods.
doi_str_mv	10.1016/j.ultras.2009.09.006
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In dielectric materials, external electric fields influence the strain response, particularly in ferroelectrics. Experiments to study this connection at phase transformations are planned. The fact that many geological samples contain single crystal quartz suggests a possible use of the piezoelectric response to drive vibrations using applied RF fields. In polycrystals, averaging of strains in randomly oriented crystals implies using the “statistical residual” strain as the drive. The ability to excite vibrations in quartzite polycrystals and arenites is explored. 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subjects	Acoustical measurements and instrumentation Acoustics Cross-disciplinary physics: materials science rheology Dielectric Elasticity Electric fields Exact sciences and technology Fundamental areas of phenomenology (including applications) Materials science Materials testing Physics Polycrystals Quartzite Resonances Surface waves Transduction acoustical devices for the generation and reproduction of sound
title	Electric field effects in RUS measurements
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