Anomalous Nonlinear Dynamics Behavior of Fractional Viscoelastic Structures
Fractional models and their parameters are sensitive to changes in the intrinsic micro-structures of anomalous materials. We investigate how such physics-informed models propagate the evolving anomalous rheology to the nonlinear dynamics of mechanical systems. In particular, we analyze the vibration...
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Zusammenfassung: | Fractional models and their parameters are sensitive to changes in the
intrinsic micro-structures of anomalous materials. We investigate how such
physics-informed models propagate the evolving anomalous rheology to the
nonlinear dynamics of mechanical systems. In particular, we analyze the
vibration of a fractional, geometrically nonlinear viscoelastic cantilever
beam, under base excitation and free vibration, where the viscoelastic response
is general through a distributed-order fractional model. We employ Hamilton's
principle to obtain the corresponding equation of motion with the choice of
specific material distribution functions that recover a fractional Kelvin-Voigt
viscoelastic model of order $\alpha$. Through spectral decomposition in space,
the resulting time-fractional partial differential equation reduces to a
nonlinear time-fractional ordinary differential equation, in which the linear
counterpart is numerically integrated by employing a direct L1-difference
scheme. We further develop a semi-analytical scheme to solve the nonlinear
system through a method of multiple scales, which yields a cubic algebraic
equation in terms of the frequency. Our numerical results suggest a set of
$\alpha$-dependent anomalous dynamic qualities, such as far-from-equilibrium
power-law amplitude decay rates, super-sensitivity of amplitude response at
free vibration, and bifurcation in steady-state amplitude at primary resonance. |
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DOI: | 10.48550/arxiv.2009.12214 |