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Main Authors: Crespo, Mewen, Guy, Casale, Marrec, Loïc Le, Neff, Patrizio
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.13098
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author Crespo, Mewen
Guy, Casale
Marrec, Loïc Le
Neff, Patrizio
author_facet Crespo, Mewen
Guy, Casale
Marrec, Loïc Le
Neff, Patrizio
contents The present work introduces a family of beam models derived from a three-dimensional higher-order elasticity framework. By incorporating three kinematic fields - the macroscopic displacement u, the micro-distortion tensor P, and the third-order tensor N - the study systematically explores three regimes: holonomic, semi-holonomic, and non-holonomic. These regimes correspond to varying levels of kinematic constraints, ranging from classical elasticity to a fully relaxed model. The holonomic case reduces to a higher-order Euler--Bernoulli beam model, while the semi-holonomic case generalises the Timoshenko beam model. The non-holonomic case provides a unified framework that naturally incorporates both dislocations and disclinations. Furthermore, the holonomic and semi-holonomic models are shown to emerge as singular limits of the non-holonomic model by increasing specific penalty coefficients. Simplified ordinary differential equation systems are derived for specific cases, such as pure traction and bending, illustrating the practical applicability of the models. The results highlight the hierarchical structure of the proposed framework and its ability to capture material defects in beam-like structures.
format Preprint
id arxiv_https___arxiv_org_abs_2507_13098
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle A New Framework for Unidimensional Structures Based on Generalised Continua
Crespo, Mewen
Guy, Casale
Marrec, Loïc Le
Neff, Patrizio
Analysis of PDEs
Classical Physics
The present work introduces a family of beam models derived from a three-dimensional higher-order elasticity framework. By incorporating three kinematic fields - the macroscopic displacement u, the micro-distortion tensor P, and the third-order tensor N - the study systematically explores three regimes: holonomic, semi-holonomic, and non-holonomic. These regimes correspond to varying levels of kinematic constraints, ranging from classical elasticity to a fully relaxed model. The holonomic case reduces to a higher-order Euler--Bernoulli beam model, while the semi-holonomic case generalises the Timoshenko beam model. The non-holonomic case provides a unified framework that naturally incorporates both dislocations and disclinations. Furthermore, the holonomic and semi-holonomic models are shown to emerge as singular limits of the non-holonomic model by increasing specific penalty coefficients. Simplified ordinary differential equation systems are derived for specific cases, such as pure traction and bending, illustrating the practical applicability of the models. The results highlight the hierarchical structure of the proposed framework and its ability to capture material defects in beam-like structures.
title A New Framework for Unidimensional Structures Based on Generalised Continua
topic Analysis of PDEs
Classical Physics
url https://arxiv.org/abs/2507.13098