Stochastic Analysis of a Nonlocal Fractional Viscoelastic Bar Forced by Gaussian White Noise

Alotta, Gioacchino; Failla, Giuseppe; Pinnola, Francesco Paolo

doi:10.1115/1.4036702

Cited by 13 publications

(10 citation statements)

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“…In fact, in nonlocal problem the stress (or the strain) at a point of the continuum is function of the stress (or strain) field of the entire domain [28,29]. Size-effects at small scale [30], strain and stress localizations [31,32], anomalous waves dispersions in complex materials with marked microstructures [33,34], structures forced by long-range force field [35][36][37] are some examples where nonlocal phenomena cannot be neglected. Among the various nonlocal models, Eringen's formulation is probably the most famous one [38,39].…”

Section: Introductionmentioning

confidence: 99%

On the nonlocal bending problem with fractional hereditariness

et al. 2021

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Nonlocal hereditariness in Bernoulli–Euler beam is investigated in this paper. An approach to solve that problem is proposed and some analytical solutions are provided. To this aim, time-dependent hereditary behavior is modeled by means of non-integer order operators of the fractional linear viscoelasticity. While, space-dependent nonlocal phenomena are simulated through the integral stress-driven formulation. These two approaches are combined providing a new model able to simulate nonlocal viscoelastic bending problem. Several application samples of the proposed formulation and a thorough parametric study are presented showing the influences of hereditariness and nonlocal effects on the mechanical bending response. Proposed formulation can be useful for design and optimization of structures used in advanced applications when local elastic theory cannot be adopted.

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Section: Introductionmentioning

confidence: 99%

On the nonlocal bending problem with fractional hereditariness

et al. 2021

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“…More recently, the peridynamic model has been proposed [10], which relates the derivative of stress to an integral involving difference of displacements through a (peridynamic) kernel. The nonlocal elasticity theory allows to study the behaviour of beams at the nano-scale [11,12], also considering the Timoshenko model [13][14][15], the presence of viscoelastic foundation [16], the response to stochastic actions [17][18][19], and allows considering plane elements at the nano-scale [20,21]. A variational approach can also be used [22] and the effect of boundary conditions on the vibration of the beam can be evaluated [23,24].…”

Section: Introductionmentioning

confidence: 99%

Dynamics of Nonlocal Rod by Means of Fractional Laplacian

et al. 2020

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The use of fractional models to analyse nonlocal behaviour of solids has acquired great importance in recent years. The aim of this paper is to propose a model that uses the fractional Laplacian in order to obtain the equation ruling the dynamics of nonlocal rods. The solution is found by means of numerical techniques with a discretisation in the space domain. At first, the proposed model is compared to a model that uses Eringen’s classical approach to derive the differential equation ruling the problem, showing how the parameters used in the proposed fractional model can be estimated. Moreover, the physical meaning of the model parameters is assessed. The model is then extended in dynamics by means of a discretisation in the time domain using Newmark’s method, and the responses to different dynamic conditions, such as an external load varying with time and free vibrations due to an initial deformation, are estimated, showing the difference of behaviour between the local response and the nonlocal response. The obtained results show that the proposed model can be used efficiently to estimate the response of the nonlocal rod both to static and dynamic loads.

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“…This approach has been recently overcome by some of the authors introducing a mechanically based model of material long-range interactions [18] that generalizes the peridynamics approach presented at the beginning of the century [19], in the sense that it involves both local and non-local interactions. Several studies of the mechanically based non-local mechanics have been presented in recent scientific literature [20][21][22][23][24] also involving fractional-order calculus, that is a generalization of the well-known classical differential calculus in terms of real (or complex) order of differintegration [25,26].…”

Section: Introductionmentioning

confidence: 99%

“…These forces are transmitted to relatively long distance by relatively large cells, mainly Red Blood Cells (RBC). These long-range interactions are constructed as volume viscous forces scaled by an attenuation function that decreases the forces mutually exerted by two nonadjacent volume elements as the distance between them increases; the approach is analogous of that successfully used in various micro/nanomechanics problems [20][21][22][23][24]. It is shown that if the attenuation function is chosen as a power law of the distance between two volume elements, the integral representing non-local forces reverts to a fractional derivative operator.…”

Section: Introductionmentioning

confidence: 99%

A Fractional Approach to Non-Newtonian Blood Rheology in Capillary Vessels

Alotta

Failla

et al. 2019

J Peridyn Nonlocal Model

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In small arterial vessels, fluid mechanics involving linear viscous fluid does not reproduce experimental results that correspond to non-parabolic profiles of velocity across the vessel diameter. In this paper, an alternative approach is pursued introducing long-range interactions that describe the interactions of non-adjacent fluid volume elements due to the presence of red blood cells and other dispersed cells in plasma. These non-local forces are defined as linearly dependent on the product of the volumes of the considered elements and on their relative velocity. Moreover, as the distance between two volume elements increases, the non-local forces decay with a material distance-decaying function. Assuming that decaying function belongs to a power-law functional class of real order, a fractional operator of the relative velocity appears in the resulting governing equation. It is shown that the mesoscale approach involving Hagen-Poiseuille law is able to reproduce experimentally measured profiles of velocity with a great accuracy. Additionally as the dimension of the vessel increases, non-local forces become negligible and the proposed model reverts to the classical Hagen-Poiseuille model.

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Stochastic Analysis of a Nonlocal Fractional Viscoelastic Bar Forced by Gaussian White Noise

Cited by 13 publications

References 50 publications

On the nonlocal bending problem with fractional hereditariness

On the nonlocal bending problem with fractional hereditariness

Dynamics of Nonlocal Rod by Means of Fractional Laplacian

A Fractional Approach to Non-Newtonian Blood Rheology in Capillary Vessels

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