Fractional order models for the homogenization and wave propagation analysis in periodic elastic beams

“…Note that the computational cost involved following f‐EFG is lower than that of the FE solvers for fractional‐order governing differential equations 28 . This is true even for a given number of nodes $$$ n $$$, but as observed in Section 4.1 the convergence via f‐EFG is achieved for a lower number of nodes.…”

Element‐free Galerkin method for a fractional‐order boundary value problem

“…Note that the computational cost involved following f‐EFG is lower than that of the FE solvers for fractional‐order governing differential equations 28 . This is true even for a given number of nodes $$$ n $$$, but as observed in Section 4.1 the convergence via f‐EFG is achieved for a lower number of nodes.…”

Element‐free Galerkin method for a fractional‐order boundary value problem

“…The fractional-order finite element method developed by the authors in a previous study (see references in ref. [1]) is used to simulate the response of the periodic beam. The fractional-order framework is validated, at both band-pass and band-gap frequencies, by direct comparison against the response of a periodic beam solved via the traditional finite element method based on integer-order equations.…”

“…Remarkably, the fractional-order homogenization approach proves capable of representing the dynamic behaviour of a bi-material periodic beam within the first few frequency band gaps, which is a strength of the proposed method over classical homogenization techniques whose range of validity is limited to the lowfrequency regime. A discussion on potential improvements is also given [1]. Lazopoulos and Lazopoulos [2] propose a novel fractional approach to continuum mechanics, based on the definition of a fractional Λ -derivative and an associated Λ-space to introduce consistent Λ-fractional strain measures, as well as corresponding stress and displacement measures.…”

“…The first group of articles concerns fractional models [1][2][3][4]. Patnaik et al [1] propose a fractional-order homogenization approach to model the elastic wave propagation in a bi-material periodic beam, taken as a representative of a one-dimensional elastic metamaterial.…”

“…The first group of articles concerns fractional models [1][2][3][4]. Patnaik et al [1] propose a fractional-order homogenization approach to model the elastic wave propagation in a bi-material periodic beam, taken as a representative of a one-dimensional elastic metamaterial. The authors assume the homogenized beam is governed by a fractional-order equation analogue of the Euler-Bernoulli beam equation, where fractionalorder kinematic relations involving a space-fractional Riesz-Caputo derivative are defined over a nonlocal horizon.…”

New prospects in non-conventional modelling of solids and structures

Damage identification in scale sensitive beam-like nano-joints in the framework of space-fractional Euler–Bernoulli theory