Mechanical Spectroscopy and Relaxation Phenomena in Solids

Leszek B. Magalas; B.M. Darinskii

doi:10.4028/www.scientific.net/SSP.115.1

Paper Titles

Mechanical Spectroscopy and Relaxation Phenomena in Solids
p.1

Determination of the Logarithmic Decrement in Mechanical Spectroscopy
p.7

Mechanical Spectroscopy, Internal Friction and Relaxation Phenomena in Solids – Suggested Reading
p.15

Mechanical Spectroscopy of Quasicrystals
p.25

The Snoek Effect in Ternary BCC Alloys. A Review
p.37

Hydrogen Interaction with Dissolved Atoms and Relaxation Properties of Metal Solid Solutions
p.41

Diffusion of Hydrogen in the Ni₃₀Ti₅₀Cu₂₀ Shape Memory Alloy
p.51

Specific Properties of Industrial High-Damping Fe-Al Steels
p.57

Ultrasonic Investigation of the Ni₄₀Ti₅₀Cu₁₀ Alloy
p.63

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Mechanical Spectroscopy and Relaxation Phenomena in Solids

Abstract:

Mechanical spectroscopy and relaxation phenomena in solids are briefly discussed from the viewpoint of generalized susceptibility and linear response theory. Comparison of mechanical spectroscopy with other spectroscopic techniques is provided in the endeavour to formulate a multidisciplinary approach to selected relaxation phenomena in solids.

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Solid State Phenomena (Volume 115)

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1-6

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.115.1

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Online since:

August 2006

Authors:

Leszek B. Magalas, B.M. Darinskii

Keywords:

Complex Compliance, Complex Modulus, Debye Relaxation, Mechanical Spectroscopy, Non-Debye Relaxation, Relaxation Phenomena

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