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    Elastic Constants and Internal Friction of Advanced Materials

    New search for: Hirao, Masahiko
    New search for: Ogi, Hirotsugu

    Abstract Resonant ultrasound spectroscopy (RUS) (Demarest, 1971; Ohno, 1976; Maynard, 1996; Migliori and Sarrao, 1997; Leisure and Willis, 1997) is recognized as a useful method to determine elastic constants of solids, including those with a lower crystallographic symmetry. The usual RUS configuration consists of a well-shaped specimen such as sphere, cylinder, or rectangular parallelepiped and two piezoelectric transducers that sandwich the specimen at opposite corners. The specimen dimensions are typically 1 to 10 mm. One transducer feeds a continuous-wave (CW) sinusoidal vibration and the other detects ultrasonic oscillation. Sweeping frequency, the received amplitude shows peaks at the free-vibration resonance frequencies of the specimen. The frequency response of the amplitude, or the resonance spectrum, thus includes many resonance peaks. The resonance frequencies are then used in an inverse calculation to find the set of elastic constants that give the measured resonance frequencies.

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    Elastic Constants and Internal Friction of Advanced Materials

    New search for: Hirao, Masahiko
    New search for: Ogi, Hirotsugu

    Abstract Resonant ultrasound spectroscopy (RUS) (Demarest, 1971; Ohno, 1976; Maynard, 1996; Migliori and Sarrao, 1997; Leisure and Willis, 1997) is recognized as a useful method to determine elastic constants of solids, including those with a lower crystallographic symmetry. The usual RUS configuration consists of a well-shaped specimen such as sphere, cylinder, or rectangular parallelepiped and two piezoelectric transducers that sandwich the specimen at opposite corners. The specimen dimensions are typically 1 to 10 mm. One transducer feeds a continuous-wave (CW) sinusoidal vibration and the other detects ultrasonic oscillation. Sweeping frequency, the received amplitude shows peaks at the free-vibration resonance frequencies of the specimen. The frequency response of the amplitude, or the resonance spectrum, thus includes many resonance peaks. The resonance frequencies are then used in an inverse calculation to find the set of elastic constants that give the measured resonance frequencies.

    Access

    Check access
    Check availability in my library
    Order at Subito €

    Elastic Constants and Internal Friction of Advanced Materials

    New search for: Hirao, Masahiko
    New search for: Ogi, Hirotsugu

    Abstract Resonant ultrasound spectroscopy (RUS) (Demarest, 1971; Ohno, 1976; Maynard, 1996; Migliori and Sarrao, 1997; Leisure and Willis, 1997) is recognized as a useful method to determine elastic constants of solids, including those with a lower crystallographic symmetry. The usual RUS configuration consists of a well-shaped specimen such as sphere, cylinder, or rectangular parallelepiped and two piezoelectric transducers that sandwich the specimen at opposite corners. The specimen dimensions are typically 1 to 10 mm. One transducer feeds a continuous-wave (CW) sinusoidal vibration and the other detects ultrasonic oscillation. Sweeping frequency, the received amplitude shows peaks at the free-vibration resonance frequencies of the specimen. The frequency response of the amplitude, or the resonance spectrum, thus includes many resonance peaks. The resonance frequencies are then used in an inverse calculation to find the set of elastic constants that give the measured resonance frequencies.

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    Title:

    Elastic Constants and Internal Friction of Advanced Materials

    Contributors:

    Hirao, Masahiko (author) / Ogi, Hirotsugu (author)

    Published in:

    EMATs for Science and Industry ; 135-192

    Publication date:

    2003-01-01

    Size:

    58 pages

    ISBN:

    978-1-4419-5366-7 , 978-1-4757-3743-1

    DOI:

    https://doi.org/10.1007/978-1-4757-3743-1_8

    Type of media:

    Article/Chapter (Book)

    Type of material:

    Electronic Resource

    Language:

    English

    Keywords:

    Resonance Frequency , Elastic Constant , Internal Friction , Vibration Group , EMAR Method Physics , Optics and Electrodynamics , Characterization and Evaluation of Materials , Measurement Science and Instrumentation , Mechanics

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