Singularities in Elliptic Boundary Value Problems and Elasticity and Their Connection with Failure Initiation

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This introductory and self-contained book gathers as much explicit mathematical results on the linear-elastic and heat-conduction solutions in the neighborhood of singular points in two-dimensional domains, and singular edges and vertices in three-dimensional domains. These are presented in an engineering terminology for practical usage. The author treats the mathematical formulations from an engineering viewpoint and presents high-order finite-element methods for the computation of singular solutions in isotropic and anisotropic materials, and multi-material interfaces. The proper interpretation of the results in engineering practice is advocated, so that the computed data can be correlated to experimental observations.

The book is divided into fourteen chapters, each containing several sections.

Most of it (the first nine Chapters) addresses two-dimensional domains, where

only singular points exist. The solution in a vicinity of these points admits an asymptotic expansion composed of eigenpairs and associated generalized flux/stress intensity factors (GFIFs/GSIFs), which are being computed analytically when possible or by finite element methods otherwise. Singular points associated with weakly coupled thermoelasticity in the vicinity of singularities are also addressed and thermal GSIFs are computed. The computed data is important in engineering practice for predicting failure initiation in brittle material on a daily basis. Several failure laws for two-dimensional domains with V-notches are presented and their validity is examined by comparison to experimental observations. A sufficient simple and reliable condition for predicting failure initiation (crack formation) in micron level electronic devices, involving singular points, is still a topic of active research and interest, and is addressed herein.

Explicit singular solutions in the vicinity of vertices and edges in three-dimensional domains are provided in the remaining five chapters. New methods for the computation of generalized edge flux/stress intensity functions along singular edges are presented and demonstrated by several example problems from the field of fracture mechanics; including anisotropic domains and bimaterial interfaces. Circular edges are also presented and the author concludes with some remarks on open questions.

This well illustrated book will appeal to both applied mathematicians and engineers working in the field of fracture mechanics and singularities.

Author(s): Zohar Yosibash (auth.)
Series: Interdisciplinary Applied Mathematics 37
Edition: 1
Publisher: Springer-Verlag New York
Year: 2012

Language: English
Pages: 462
Tags: Computational Mathematics and Numerical Analysis; Theoretical and Applied Mechanics; Appl.Mathematics/Computational Methods of Engineering

Front Matter....Pages i-xxi
Introduction....Pages 1-25
An Introduction to the p- and hp-Versions of the Finite Element Method....Pages 27-45
Eigenpair Computation for Two-Dimensional Heat Conduction Singularities....Pages 47-72
GFIFs Computation for Two-Dimensional Heat Conduction Problems....Pages 73-95
Eigenpairs for Two-Dimensional Elasticity....Pages 97-132
Computing Generalized Stress Intensity Factors (GSIFs)....Pages 133-156
Thermal Generalized Stress Intensity Factors in 2-D Domains....Pages 157-183
Failure Criteria for Brittle Elastic Materials....Pages 185-220
A Thermoelastic Failure Criterion at the Micron Scale in Electronic Devices....Pages 221-236
Singular Solutions of the Heat Conduction (Scalar) Equation in Polyhedral Domains....Pages 237-264
Extracting Edge-Flux-Intensity Functions (EFIFs) Associated with Polyhedral Domains....Pages 265-290
Vertex Singularities for the 3-D Laplace Equation....Pages 291-314
Edge EigenPairs and ESIFs of 3-D Elastic Problems....Pages 315-375
Remarks on Circular Edges and Open Questions....Pages 377-393
Definition of Sobolev, Energy, and Statically Admissible Spaces and Associated Norms....Pages 395-399
Analytic Solution to 2-D Scalar Elliptic Problems in Anisotropic Domains....Pages 401-410
Asymptotic Solution at the Intersection of Circular Edges in a 2-D Domain....Pages 411-416
Proof that Eigenvalues of the Scalar Anisotropic Elliptic BVP with Constant Coefficients Are Real....Pages 417-419
A Path-Independent Integral and Orthogonality of Eigenfunctions for General Scalar Elliptic Equations in 2-D Domains....Pages 421-425
Energy Release Rate (ERR) Method, its Connection to the J-integral and Extraction of SIFs....Pages 427-446
Back Matter....Pages 447-459