Bending problems in the theory of elastic materials with voids and surface effects

Lurie, S. A.; Solyaev, Yury; Волков, А. А.; Volkov-Bogorodskiy, D. B.

doi:10.1177/1081286517691570

Cited by 18 publications

(13 citation statements)

References 33 publications

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“…An increase in this function results in a decrease of the apparent elastic constants at a given point of the medium [10,13,35,42]. Apparent elastic stiffness is also reduced when increasing strain/micro-dilatation coupling effects [41]. In the present work, we show that the apparent elastic behavior of the considered gradient/micro-dilatation medium is more complex than those mentioned above: its apparent stiffness decreases, while the apparent length scale parameter increases, when increasing micro-dilatation effects.…”

Section: Introductionsupporting

confidence: 55%

“…It seems that the same results may be proven in the two-dimensional and three-dimensional problems by using generalized analytical and numerical approaches of strain gradient and micro-dilatation elasticity theories [36,41,58,59]. However, it might be necessary to consider more general models to describe the field of defects in materials with complex microstructure, such as micropolar, microstretch, or general micromorphic [9].…”

Section: Discussionmentioning

confidence: 99%

“…In [12, 13, 41] it has been shown that additional scalar field variables introduced in micro-dilatation elasticity can be treated as fields of defects. An increase in this function results in a decrease of the apparent elastic constants at a given point of the medium [10, 13, 35, 42].…”

Section: Introductionmentioning

confidence: 99%

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On the dependence of standard and gradient elastic material constants on a field of defects

Solyaev¹,

Lurie

Barchiesi

et al. 2019

Mathematics and Mechanics of Solids

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In this work, we consider a strain gradient elasticity theory with an extended number of field variables: the displacement vector and an additional scalar field defining the internal micro-deformation. The total internal energy of the model depends on the strain, the micro-deformation function, their gradients, and the coupling. The considered model can be treated as gradient/micromorphic. Moreover, the micro-deformation field can be treated as a field of scalar defects distributed along the medium. Based on analytic (one-dimensional) solutions of uniform/non-uniform deformation of the rod, we introduce (i) an apparent stiffness and (ii) an apparent length scale parameter. Subsequently, we provide a variant of continuum-on-continuum homogenization by equating tip displacements for the gradient/micromorphic medium and an equivalent strain gradient one. Elongation of the gradient/micromorphic rod is therefore equated with the corresponding elongation of the equivalent strain gradient rod, whose behavior is characterized by the apparent material constants. Subsequently, the non-dimensional coupling number is identified with a damage parameter. It is shown that, on the one hand, the apparent stiffness of the rod is reduced when such parameter increases. On the other hand, the apparent length scale parameter (i.e. the apparent second gradient elastic coefficient) increases when the damage parameter increases. Therefore, it is shown that the presence of defects in a second gradient linear elastic material may increase its apparent strain gradient behavior.

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Section: Introductionsupporting

confidence: 55%

Section: Discussionmentioning

confidence: 99%

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On the dependence of standard and gradient elastic material constants on a field of defects

Solyaev¹,

Lurie

Barchiesi

et al. 2019

Mathematics and Mechanics of Solids

Self Cite

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“…In poromechanics (see, e.g., Lurie et al (2018); Khalili and Selvadurai (2003); Misra et al ( , 2013), and coherently to what done in the Biot model, we introduce the Lagrangian field ζ(X, t) defined as the change of the effective volume of the voids per unit volume in the transformation from Lagrangian to Eulerian configuration. In formulas…”

Section: Basic Kinematical Fields and Fundamental Modeling Assumptionsmentioning

confidence: 99%

On mechanically driven biological stimulus for bone remodeling as a diffusive phenomenon

Giorgio¹,

Dell’Isola²,

Andreaus³

et al. 2019

Biomech Model Mechanobiol

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In the past years, many attempts have been made in order to model the process of bone remodeling. This process is complex, as it is governed by not yet completely understood biomechanical coupled phenomena. It is well known that bone tissue is able to self-adapt to different environmental demands of both mechanical and biological origin. The mechanical aspects are related to the functional purpose of the bone tissue, i.e., to provide support to the body and protection for the vitally important organs in response to the external loads. The many biological aspects include the process of oxygen and nutrients supply. To describe the biomechanical process of functional adaptation of bone tissue, the approach commonly

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“…Since the bone tissue is a porous material, a first attempt to generalize its mechanical description involves adopting a micromorphic model in which to the standard kinematic variables is added a further quantity that takes into account the change of porosity of the tissue, as in the classical models developed by Biot and his followers [63][64][65][66][67][68][69] and by Cowin and Nunziato and their followers [70][71][72][73][74]. This approach is based on the energy density, and is quite common in poromechanics.…”

Section: Macro-modelsmentioning

confidence: 99%

In-depth gaze at the astonishing mechanical behavior of bone: A review for designing bio-inspired hierarchical metamaterials

Giorgio

Spagnuolo

Andreaus

et al. 2020

Mathematics and Mechanics of Solids

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In this review paper, some relevant models, algorithms, and approaches conceived to describe the bone tissue mechanics and the remodeling process are showcased. Specifically, we briefly describe the hierarchical structure of the bone at different levels and underline the geometrical substructure characterizing the bone itself. The mechanical models adopted to describe the bone tissue at different levels of observation are introduced in their essential aspects. Furthermore, the modeling of the evolution, including the growth and resorption of bone, is treated by analyzing the main approaches employed, namely the mechanical feedback concept and the structural optimization perspective. In this regard, the most prominent ways to model the biomechanical stimulus are summarized. The modeling of the interaction with prostheses or grafts commonly used in reconstructive surgery is also recalled. The main aim of this survey consists thereby in providing the appropriate knowledge to mimic the deeply structured hierarchy of the bone tissue for synthesizing innovative and highly performing bio-inspired metamaterials.

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Bending problems in the theory of elastic materials with voids and surface effects

Cited by 18 publications

References 33 publications

On the dependence of standard and gradient elastic material constants on a field of defects

On the dependence of standard and gradient elastic material constants on a field of defects

On mechanically driven biological stimulus for bone remodeling as a diffusive phenomenon

In-depth gaze at the astonishing mechanical behavior of bone: A review for designing bio-inspired hierarchical metamaterials

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