Sage Journals: Discover world-class research

Abstract

For any body-time manifold $R \times B$ there exists a groupoid, called the material groupoid, encoding all the material properties of the material evolution. A smooth distribution, the material distribution, is constructed to deal with the case in which the material groupoid is not a Lie groupoid. This new tool provides a unified framework to deal with general non-uniform material evolution.

Keywords

Lie groupoid uniformity material groupoid material evolution remodeling

Get full access to this article

View all access options for this article.

References

Noll

On the continuity of the solid and fluid states. J Rational Mech Anal 1955; 4: 3–81.

Noll

Materially uniform bodies with inhomogeneities. Arch Rational Mech Anal 1967; 27: 1–32.

Elżanowski

Epstein

Śniatycki

G

-structures and material homogeneity. J Elasticity 1990; 23(2–3): 167–180.

Ehresmann

Catégories topologiques et catégories différentiables. In: Colloque Géom. Diff. Globale (Bruxelles, 1958). Louvain: Centre Belge Rech. Math., 1959, pp. 137–150.

de León

Epstein

Jiménez

. Material Geometry: Groupoids in Continuum Mechanics. Singapore: World Scientific, 2021.

Jiménez

de León

Epstein

Characteristic distribution: An application to material bodies. J Geom Phys 2018; 127: 19–31.

Epstein

Jiménez

de León

Material geometry. J Elasticity 2019; 135(1): 237–260.

Jiménez

de León

Epstein

Material distributions. Math Mech Solids 2017; 25(7): 1450–1458.

Epstein

Mathematical characterization and identification of remodeling, growth, aging and morphogenesis. J Mech Phys Solids 2015; 84: 72–84.

10.

Epstein

de León

Unified geometric formulation of material uniformity and evolution. Math Mech Complex Syst 2016; 4(1): 17–29.

11.

Epstein

Elzanowski

Material inhomogeneities and their evolution: A geometric approach. In: Interaction of Mechanics and Mathematics. Berlin: Springer, 2007.

12.

Rodriguez

Hoger

McCulloch

AD.

Stress-dependent finite growth in soft elastic tissues. J Biomech 1994; 27(4): 455–467.

13.

Turner

CH.

On Wolff’s law of trabecular architecture. J Biomech 1992; 25(1): 1–9.

14.

Mackenzie

KCH.

General theory of Lie groupoids and Lie algebroids (London Mathematical Society Lecture Note Series, Vol. 213). Cambridge: Cambridge University Press, 2005.

15.

Valdés

Villalón

ÁFT

Alarcón

JAV

. Elementos de la teora de grupoides y algebroides. Cádiz: Universidad de Cádiz, Servicio de Publicaciones, 2006.

16.

Jiménez

de León

Epstein

On the Homogeneity of Non-uniform Material Bodies. Berlin: Springer, 2020, pp. 381–416.

17.

Brandt

Über eine Verallgemeinerung des Gruppenbegriffes. Math Ann 1927; 96(1): 360–366.

18.

Ehresmann

Les connexions infinitésimales dans un espace fibré différentiable. In: Séminaire Bourbaki, Vol. 1. Paris: Soc. Math. France, 1995, Exp. No. 24, pp. 153–168.

19.

Ehresmann

Les prolongements d’une variété différentiable. V. Covariants différentiels et prolongements d’une structure infinitésimale. C R Acad Sci Paris 1952; 234: 1424–1425.

20.

Ehresmann

Sur les connexions d’ordre supérieur. In Dagli Atti del V Congresso dell’Unione Matematica Italiana. Pavia-Torino: Un. Mat. Italiana, 1956, pp. 344–346.

21.

Pradines

Théorie de Lie pour les groupoïdes différentiables. Relations entre propriétés locales et globales. C R Acad Sci Paris Sér A-B 1966; 263: A907–A910.

22.

Epstein

The Geometrical Language of Continuum Mechanics. Cambridge: Cambridge University Press, 2010.

23.

Weinstein

Groupoids: Unifying internal and external symmetry. A tour through some examples. In: Groupoids in Analysis, Geometry, and Physics Boulder, CO, 1999) (Contemporary Mathematics, Vol. 282). Providence, RI: American Mathematical Society, 2001, pp. 1–19.

24.

Saunders

DJ.

The Geometry of Jet Bundles (London Mathematical Society Lecture Note Series). Cambridge: Cambridge University Press, 1989.

25.

Stefan

Accessible sets, orbits, and foliations with singularities. Proc London Math Soc (3) 1974; 29: 699–713.

26.

Sussmann

HJ.

Orbits of families of vector fields and integrability of distributions. Trans Amer Math Soc 1973; 180: 171–188.

27.

Wang

Truesdell

Introduction to Rational Elasticity. Leyden: Noordhoff International Publishing, 1973.

28.

Marsden

Hughes

TJR

. Mathematical Foundations of Elasticity. New York: Dover, 1994.

29.

Elżanowski

Prishepionok

Locally homogeneous configurations of uniform elastic bodies. Rep Math Phys 1992; 31(3): 329–340.

30.

Wang

CC.

On the geometric structures of simple bodies. A mathematical foundation for the theory of continuous distributions of dislocations. Arch Rat Mech Anal 1967; 27: 33–94.

31.

Bloom

Modern Differential Geometric Techniques in the Theory of Continuous Distributions of Dislocations (Lecture Notes in Mathematics, Vol. 733). Berlin: Springer, 1979.

32.

Maugin

GA.

Material Inhomogeneities in Elasticity (Applied Mathematics and Mathematical Computation, Vol. 3). London: Chapman & Hall, 1993.

33.

Jiménez

de León

Epstein

Lie groupoids and algebroids applied to the study of uniformity and homogeneity of material bodies. J Geom Mech 2019; 11(3): 301–324.

34.

Epstein

de León

Material groupoids and algebroids. Math Mech Solids 2019; 24(3): 796–806.

35.

Jiménez

de León

Epstein

Lie groupoids and algebroids applied to the study of uniformity and homogeneity of Cosserat media. Int J Geom Meth Mod Phys 2018; 15(08): 1830003.

Characteristic foliations of material evolution: from remodeling to aging

Abstract

Keywords

Get full access to this article

References