Abstract We present a new rheological model depending on a real parameter ν ∈ [0, 1], which reduces to the Maxwell body for ν = 0 and to the Becker body for ν = 1. The cor- responding creep law is expressed in an integral form in which the exponential function of the Becker model is replaced and generalized by a Mittag–Leffler function of order ν. Then the corresponding non-dimensional creep function and its rate are studied as functions of time for different values of ν in order to visualize the transition from the classical Maxwell body to the Becker body. Based on the hereditary theory of linear viscoelasticity, we also approximate the relaxation function by solving numerically a Volterra integral equation of the second kind. In turn, the relaxation function is shown versus time for different values of ν to visualize again the transition from the classical Maxwell body to the Becker body. Furthermore, we provide a full characterization of the new model by computing, in addition to the creep and relaxation functions, the so-called specific dissipation Q−1 as a function of frequency, which is of particular relevance for geophysical applications.
Mainardi, F., Masina, E., Spada, G. (2019). A generalization of the Becker model in linear viscoelasticity: creep, relaxation and internal friction. MECHANICS OF TIME-DEPENDENT MATERIALS, 23(3), 283-294 [10.1007/s11043-018-9381-4].
A generalization of the Becker model in linear viscoelasticity: creep, relaxation and internal friction
Spada, Giorgio
2019
Abstract
Abstract We present a new rheological model depending on a real parameter ν ∈ [0, 1], which reduces to the Maxwell body for ν = 0 and to the Becker body for ν = 1. The cor- responding creep law is expressed in an integral form in which the exponential function of the Becker model is replaced and generalized by a Mittag–Leffler function of order ν. Then the corresponding non-dimensional creep function and its rate are studied as functions of time for different values of ν in order to visualize the transition from the classical Maxwell body to the Becker body. Based on the hereditary theory of linear viscoelasticity, we also approximate the relaxation function by solving numerically a Volterra integral equation of the second kind. In turn, the relaxation function is shown versus time for different values of ν to visualize again the transition from the classical Maxwell body to the Becker body. Furthermore, we provide a full characterization of the new model by computing, in addition to the creep and relaxation functions, the so-called specific dissipation Q−1 as a function of frequency, which is of particular relevance for geophysical applications.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.