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Material Inhomogeneities and their Evolution: A Geometric Approach 2007 ed. [Mīkstie vāki]

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  • Formāts: Paperback / softback, 261 pages, height x width: 235x155 mm, weight: 444 g, XIII, 261 p., 1 Paperback / softback
  • Sērija : Interaction of Mechanics and Mathematics
  • Izdošanas datums: 05-Sep-2007
  • Izdevniecība: Springer-Verlag Berlin and Heidelberg GmbH & Co. K
  • ISBN-10: 3540723722
  • ISBN-13: 9783540723721
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Material Inhomogeneities and their Evolution: A Geometric Approach 2007 ed.Palielināt
  • Formāts: Paperback / softback, 261 pages, height x width: 235x155 mm, weight: 444 g, XIII, 261 p., 1 Paperback / softback
  • Sērija : Interaction of Mechanics and Mathematics
  • Izdošanas datums: 05-Sep-2007
  • Izdevniecība: Springer-Verlag Berlin and Heidelberg GmbH & Co. K
  • ISBN-10: 3540723722
  • ISBN-13: 9783540723721
Citas grāmatas par šo tēmu:
Permanent link: https://www.kriso.lv/db/9783540723721.html
Keywords:
With its origins in the theories of continuous distributions of dislocations and ofmetalplasticity,inhomogeneitytheoryisarichandvibrant eldofresearch. The recognition of the important role played by con gurational or material forces in phenomena such as growth and remodelling is perhaps its greatest present-day impetus. While some excellent comprehensive works approa- ing the subject from di erent angles have been published, the objective of this monograph is to present a point of view that emphasizes the di erenti- geometric aspects of inhomogeneity theory. In so doing, we follow the general lines of thought that we have propounded in many publications and presen- tions over the last two decades. Although based on these sources, this book is a stand-alone entity and contains some new results and perspectives. At the same time, it does not intend to present either a historical account of the - velopment of the subject or a comprehensive picture of the various schools of thought that can be encountered by perusing scholarly journals and attending specialized symposia. The book is divided into three parts, the ?rst of which is entirely devoted to the formulation of the theory in the absence of evolution. In other words, time is conspicuously absent from Part I. It opens with the geometric ch- acterization of material inhomogeneity within the context of simple bodies in Chapter 1, followed by extensions to second-grade and Cosserat media in Chapters 2 and 3.

Recenzijas

From the reviews:









"The objective of the present book is to present a point of view that emphasizes the differential-geometric aspect of the inhomogeneity theory. By following the presentation in the preface, the book is divided in three parts . This book is highly recommended to the workers on modern continuum mechanics." (Franco Cardin, Zentralblatt MATH, Vol. 1130 (8), 2008)



"The main goal of this book is to present a new point of view on the theory of material inhomogeneities by means of a strong mathematical tool, namely, differential geometry. useful for a reader who is interested in one of the particular topics treated. I recommend it as one of the best monographs not only on the topic of material inhomogeneities, but even in the larger domain of the differential-geometric approach to continuum mechanics." (Nicolae Boja, Mathematical Reviews, Issue 2009 e)

Part I Inhomogeneity in Continuum Mechanics
An overview of inhomogeneity theory
3(38)
The constitutive equation of a material body
3(4)
Configurations, deformations and their gradient
3(1)
Locality, simplicity, elasticity
4(3)
Material uniformity
7(13)
The notion of material isomorphism
7(3)
Material symmetries and the non-uniqueness of material isomorphisms
10(2)
The material archetype
12(4)
Local material parallelisms
16(4)
Non-uniqueness of the (local) material connection
20(1)
The material G-structure and the material groupoid
20(10)
The material G-structure
20(6)
The material groupoid and its associated G-structures
26(4)
Homogeneity
30(6)
Uniformity and homogeneity
30(1)
Homogeneity in terms of a material connection
31(2)
Homogeneity in terms of a material G-structure
33(3)
Homogeneity in terms of the material groupoid
36(1)
Homogeneity criteria
36(5)
Solids
36(2)
Fluids
38(1)
Fluid crystals
39(2)
Uniformity of second-grade materials
41(26)
An intuitive picture
41(2)
The second-grade constitutive law
43(4)
Jets of maps
43(1)
Composition of jets
44(3)
Second-grade materials
47(1)
Second-grade uniformity
47(5)
Material isomorphisms
47(1)
Second-grade material archetypes
48(1)
Second-grade symmetries
49(1)
An example of a nontrivial second-grade symmetry
50(2)
The material second-order G-structures and groupoid
52(2)
The second-order frame bundle
52(1)
The material G-structures
52(2)
The material groupoid
54(1)
The subgroups of G2(n)
54(5)
The generic subgroup
54(3)
Toupin subgroups
57(1)
The subgroups {I, ΣI} and their conjugates
58(1)
Second-grade homogeneity
59(6)
The second-order frames induced by a coordinate system
59(1)
Homogeneity
59(1)
Coordinate expressions
60(3)
Homogeneity in terms of a material G-structure
63(2)
Homogeneity in terms of the material groupoid
65(2)
Uniformity of Cosserat media
67(30)
Kinematics of a Cosserat body
67(4)
The constitutive law of a simple elastic Cosserat body
71(3)
Material isomorphisms and uniformity
74(4)
Material isomorphisms in a Cosserat body
74(1)
Uniformity and the Cosserat archetype
75(1)
Cosserat symmetries
76(1)
Changing coordinates
77(1)
Changing the archetype
78(1)
Homogeneity conditions
78(3)
Homogeneity of a Cosserat body
78(1)
The three kinds of material connections of a uniform Cosserat body
79(1)
Homogeneity conditions
80(1)
The Cosserat material G-structures and groupoid
81(10)
Frames, and frames of frames
81(4)
Non-holonomic, semi-holonomic and holonomic frames
85(5)
The Cosserat material G-structures
90(1)
The Cosserat material groupoid
91(1)
Homogeneity, flatness and integrable prolongations
91(6)
Sections of F2B
92(1)
Invariant sections and linear connections
93(1)
Prolongations
94(3)
Functionally graded bodies
97(14)
The extended notion of material isomorphism
97(1)
Non-uniqueness of symmetry isomorphisms
98(1)
The material N-structure
99(1)
Homosymmetry
100(1)
Unisymmetric homogeneity of elastic solids
101(2)
The reduced N-structure
103(3)
Algebraic preliminaries
103(1)
The N-structure of a solid functionally-graded unisymmetric body
104(2)
Examples
106(1)
The isotropic solid
106(1)
The transversely isotropic solid
106(1)
The n-agonal solids
106(1)
Orthotropic materials
107(1)
Summary
107(4)
Part II Material Evolution
On energy, Cauchy stress and Eshelby stress
111(24)
Preliminary considerations
111(1)
The Cauchy stress revisited
112(2)
Eshelby's tensor as Cauchy's dual
114(1)
Complete expressions of hyperelastic uniformity
115(1)
The Eshelby and Mandel Stresses in the Context of Material Uniformity
116(2)
Eshelby-stress identities
118(4)
Consequences of balance of angular momentum
118(1)
Consequences of a continuous symmetry group
118(1)
Consequences of the balance of linear momentum
119(1)
Inhomogeneity with compact support and the J-integral
120(2)
The Eshelby stress in thermoelasticity
122(6)
Thermoelastic uniformity
122(1)
The Eshelby stress identity
123(1)
Thermal stresses
124(3)
The material heat conduction tensor
127(1)
On stress, hyperstress and Eshelby stress in second-grade bodies
128(2)
On stress, microstress and Eshelby stress in Cosserat bodies
130(5)
Equilibrium equations
130(1)
Eshelby stresses
131(2)
Eshelby stress identities
133(2)
An overview of the theory of material evolution
135(48)
What is material evolution?
135(2)
A geometric picture
137(1)
Evolution equations
138(7)
General form
138(1)
Reduction to the archetype
139(2)
The principle of actual evolution
141(2)
Material symmetry consistency
143(2)
The field equations of remodelling and bulk growth
145(11)
Balance of mass
146(1)
Balance of linear momentum
147(1)
Balance of angular momentum
148(1)
Balance of energy
148(1)
The Clausius-Duhem inequality and its consequences
149(7)
An alternative approach
156(6)
Example: Visco-elasto-plastic theories
162(6)
A simple non-trivial model
162(1)
Some computational considerations
163(2)
Creep of a bar under uniaxial loading
165(2)
Evolution, rheological models and the Eshelby stress
167(1)
Example: Bulk growth
168(6)
Exercise stimulates growth
169(1)
A challenge to Wolff's law?
170(4)
Example: Self-driven evolution
174(9)
Introduction
174(1)
A solid crystal body
175(3)
An isotropic solid
178(5)
Second-grade evolution
183(10)
Introduction
183(1)
Reduction to the archetype
184(2)
Actual evolution
186(1)
Material symmetry consistency
186(1)
An example
187(1)
Concluding remarks
188(5)
Part III Mathematical Foundations
Basic geometric concepts
193(20)
Differentiable manifolds
193(9)
Lie groups
202(2)
Fibre bundles
204(9)
Principal fibre bundles
206(2)
Associated fibre bundles
208(3)
Sections of fibre bundles
211(2)
Theory of connections
213(22)
Connections on principal G-bundles
213(9)
Parallelism in a principal G-bundle
216(1)
Reduction of a connection
217(1)
Structure equation, curvature and holonomy
218(4)
Flat connections
222(1)
Linear connections
222(4)
Connections in an associated bundle
226(4)
G-structures
230(5)
Examples of G-structures
232(3)
Bundles of linear frames
235(8)
Jet prolongations of fibre bundles
235(2)
Local coordinates on prolongations
237(2)
Lie groups of jets of diffeomorphisms
239(1)
Higher-order frame bundles
240(3)
Connections of higher order
243(14)
Fundamental form
243(2)
ε-connection
245(3)
Second-order (holonomic) connection
248(4)
Simple connections
252(5)
Groupoids
257(6)
Introduction
257(1)
Groupoids
257(3)
Transitive Lie groupoids and principal bundles
260(3)
References 263(6)
Index 269