Determination of Elastic Properties of Crystals near Phase Transitions with Pulsed Ultrasound and Mechanical Resonance

U. Straube; Horst Beige; Volkmar Müller

doi:10.4028/www.scientific.net/SSP.89.327

Paper Titles

Influence of the Technology Conditions on the Mechanical and Dielectric Properties of the PZT-Base Piezoceramic Transducers
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Mechanical Spectroscopy and Phase Transformations in PZT-Type Piezoceramics
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Damping Capacity of Ti-Ni Shape Memory Alloys
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Mechanical Spectroscopy of Rolling Oil Films on Cold-Rolled Steel Sheets
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Determination of Elastic Properties of Crystals near Phase Transitions with Pulsed Ultrasound and Mechanical Resonance
p.327

Dispersion and Energy Losses
p.335

A New Impulse Mechanical Spectrometer to Study the Dynamic Mechanical Properties of Filaments
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A New Multifunctional Subresonant and Resonant Mechanical Spectrometer
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Selected Applications of the Wavelet Transform
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HomeSolid State PhenomenaSolid State Phenomena Vol. 89Determination of Elastic Properties of Crystals...

Determination of Elastic Properties of Crystals near Phase Transitions with Pulsed Ultrasound and Mechanical Resonance

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Solid State Phenomena (Volume 89)

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327-334

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.89.327

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Online since:

February 2003

Authors:

U. Straube, Horst Beige, Volkmar Müller

Keywords:

Acoustic Dispersion, Elastic Coefficients, Impulse Ultrasound, Phase Transition, Piezoelectric Resonator

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References

[1] B. Lüthi, W. Rehwald, Ultrasonic Studies near Phase Transitions, in Structural Phase Transitions I, Springer, Berlin, p.131 (1981).

DOI: 10.1007/978-3-642-81531-7_4

Google Scholar

[2] G. Sorge, Ultraschall in Wissenschaft und Technik, Teubner, Leipzig (1985).

Google Scholar

[3] H. Kutruff, Physik und Technik des Ultraschalls, Hirzel, Stuttgart (1988).

Google Scholar

[4] H. J. McSkimin, J. Acoust. Soc. Am. 33, 12 (1961). [5] E. P. Papadakis, J. Acoust. Soc. Am. 42, 1045 (1967).

Google Scholar

[6] H. F. Pollard, Sound Waves in Solids, London (1977).

Google Scholar

[7] R. Truell, C. Elbaum, B. Chick, Ultrasonic Methods in Solid State Physics, New York (1969).

DOI: 10.1016/b978-1-4832-3318-5.50004-3

Google Scholar

[8] H. Beige, G. Schmidt, Ferroelectrics 41 173 (1982).

Google Scholar

[9] U. Straube, H. Beige, Ferroelectrics 238, 179 (2000).

Google Scholar

[10] V. A. Sutilov, Physik des Ultraschalls: Grundlagen, Akad.-Verl., Berlin (1984).

Google Scholar

[11] K. Brugger, J. Appl. Phys. 36, 759 (1965).

Google Scholar

[12] W. G. Cady, Piezoelectricity, New York (1946).

Google Scholar

[13] W. P. Mason, Piezoelectric Crystals and their Application to Ultrasonics, New York (1950).

Google Scholar

[14] T. Ikeda, Fundamentals of Piezoelectricity, Oxford (1990).

Google Scholar

[15] Y. Makita, J. Phys. Soc. Japan, 20, 2073 (1965).

Google Scholar

[16] G. Sorge, U. Straube, N. R. Ivanov, Phys. status solidi 65, 189 (1981).

Google Scholar

[17] L. Bohaty, Z. Kristallogr. 178, 28 (1987).

Google Scholar

[18] U. Straube, V. Müller, H. Beige, to be published.

Google Scholar