Abstract
Many of the most interesting complex media are non-Newtonian and exhibit time-dependent behavior of thixotropy and rheopecty. They may also have temporal responses described by power laws. The material behavior is represented by the relaxation modulus and the creep compliance. On the one hand, it is shown that in the special case of a Maxwell model characterized by a linearly time-varying viscosity, the medium's relaxation modulus is a power law which is similar to that of a fractional derivative element often called a springpot. On the other hand, the creep compliance of the time-varying Maxwell model is identified as Lomnitz's logarithmic creep law, making this possibly its first direct derivation. In this way both fractional derivatives and Lomnitz's creep law are linked to time-varying viscosity. A mechanism which yields fractional viscoelasticity and logarithmic creep behavior has therefore been found. Further, as a result of this linking, the curve-fitting parameters involved in the fractional viscoelastic modeling, and the Lomnitz law gain physical interpretation.
Highlights
Many complex media exhibit non-Newtonian behavior, meaning that stress no longer is proportional to strain rate
II we show how the fractional derivative naturally emerges from the relaxation modulus of a time-varying Maxwell model
TIME-VARYING VISCOSITY AS A SPRINGPOT. Independent of both the fields of fractional viscoelasticity and non-Newtonian rheology, in [35] it was found that the friction between grains in a fluid-saturated sediment may be described by a time-varying Maxwell model, which consists of a spring in series with the viscosity given in Eq (4)
Summary
Many complex media exhibit non-Newtonian behavior, meaning that stress no longer is proportional to strain rate. The underlying reason is the complexity of the phenomenon, and models are often empirical and lack a proper physical interpretation [1] When it comes to time-dependent non-Newtonian rheology, there exist two quite different approaches to modeling. There have been advances in modeling time dependency with fractional calculus in which power laws are inherent [2,3,4]. These two approaches to modeling are quite distinct from each other and there are not many references from one field to the other.
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