Microstructural mechanisms such as domain switching in ferroelectric ceramics dissipate energy, the nature, and extent of which are of significant interest for two reasons. First, dissipative internal processes lead to hysteretic behavior at the macroscale (e.g., the hysteresis of polarization versus electric field in ferroelectrics). Second, mechanisms of internal friction determine the viscoelastic behavior of the material under small-amplitude vibrations. Although experimental techniques and constitutive models exist for both phenomena, there is a strong disconnect and, in particular, no advantageous strategy to link both for improved physics-based kinetic models for multifunctional rheological materials. Here, we present a theoretical approach that relates inelastic constitutive models to frequency-dependent viscoelastic parameters by linearizing the kinetic relations for the internal variables. This enables us to gain qualitative and quantitative experimental validation of the kinetics of internal processes for both quasistatic microstructure evolution and high-frequency damping. We first present the simple example of the generalized Maxwell model and then proceed to the case of ferroelectric ceramics for which we predict the viscoelastic response during domain switching and compare to experimental data. This strategy identifies the relations between microstructural kinetics and viscoelastic properties. The approach is general in that it can be applied to other rheological materials with microstructure evolution.
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February 2017
Research-Article
Linking Internal Dissipation Mechanisms to the Effective Complex Viscoelastic Moduli of Ferroelectrics
Charles S. Wojnar,
Charles S. Wojnar
Department of Mechanical and
Aerospace Engineering,
Missouri University of Science and Technology,
400 West 13th Street,
Rolla, MO 65409
e-mail: wojnarc@mst.edu
Aerospace Engineering,
Missouri University of Science and Technology,
400 West 13th Street,
Rolla, MO 65409
e-mail: wojnarc@mst.edu
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Dennis M. Kochmann
Dennis M. Kochmann
Graduate Aerospace Laboratories,
California Institute of Technology,
1200 East California Boulevard,
Pasadena, CA 91125
e-mail: kochmann@caltech.edu
California Institute of Technology,
1200 East California Boulevard,
Pasadena, CA 91125
e-mail: kochmann@caltech.edu
Search for other works by this author on:
Charles S. Wojnar
Department of Mechanical and
Aerospace Engineering,
Missouri University of Science and Technology,
400 West 13th Street,
Rolla, MO 65409
e-mail: wojnarc@mst.edu
Aerospace Engineering,
Missouri University of Science and Technology,
400 West 13th Street,
Rolla, MO 65409
e-mail: wojnarc@mst.edu
Dennis M. Kochmann
Graduate Aerospace Laboratories,
California Institute of Technology,
1200 East California Boulevard,
Pasadena, CA 91125
e-mail: kochmann@caltech.edu
California Institute of Technology,
1200 East California Boulevard,
Pasadena, CA 91125
e-mail: kochmann@caltech.edu
1Corresponding author.
Contributed by the Applied Mechanics Division of ASME for publication in the JOURNAL OF APPLIED MECHANICS. Manuscript received September 25, 2016; final manuscript received October 17, 2016; published online November 17, 2016. Assoc. Editor: A. Amine Benzerga.
J. Appl. Mech. Feb 2017, 84(2): 021006 (14 pages)
Published Online: November 17, 2016
Article history
Received:
September 25, 2016
Revised:
October 17, 2016
Citation
Wojnar, C. S., and Kochmann, D. M. (November 17, 2016). "Linking Internal Dissipation Mechanisms to the Effective Complex Viscoelastic Moduli of Ferroelectrics." ASME. J. Appl. Mech. February 2017; 84(2): 021006. https://doi.org/10.1115/1.4035033
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