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An unified formulation of strong non-local elasticity with fractional order calculus

Gioacchino Alotta, Mario Di Paola, Francesco Paolo Pinnola

2021Meccanica24 citationsDOIOpen Access PDF

Abstract

Abstract The research of a formulation to model non-local interactions in the mechanical behavior of matter is currently an open problem. In this context, a strong non-local formulation based on fractional calculus is provided in this paper. This formulation is derived from an analogy with long-memory viscoelastic models. Specifically, the same kind of power-law time-dependent kernel used in Boltzmann integral of viscoelastic stress-strain relation is used as kernel in the Fredholm non-local relation. This non-local formulation leads to stress-strain relation based on the space Riesz integral and derivative of fractional order. For unbounded domain, proposed model can be defined in stress- and in strain-driven formulation and in both cases the stress–strain relation represent a strong non-local model. Also, the proposed strain driven and stress driven formulations defined in terms of Riesz operators are proved to be fully consistent each another. Moreover, the proposed model posses a mechanical meaning and for unbounded non-local rod is described and discussed in detail.

Topics & Concepts

Fractional calculusMathematicsViscoelasticityKernel (algebra)Context (archaeology)Relation (database)Elasticity (physics)Domain (mathematical analysis)Applied mathematicsCalculus (dental)Mathematical analysisPure mathematicsComputer sciencePhysicsDatabaseDentistryThermodynamicsBiologyMedicinePaleontologyNumerical methods in engineeringNonlocal and gradient elasticity in micro/nano structuresFractional Differential Equations Solutions