Brittle Fracture and Damage of Brittle Materials and Composites
Statistical-Probabilistic Approaches

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Language: English

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Flaws are the principal source of fracture in many materials, whether brittle or ductile, whether nearly homogeneous or composite. They are introduced during either fabrication or surface preparation or during exposure to aggressive environments (e. g. oxidation, shocks). The critical flaws act as stress concentrators and initiate cracks that propagate instantaneously to failure in the absence of crack arrest phenomena as encountered in brittle materials.

This book explores those brittle materials susceptible to crack arrest and the flaws which initiate crack induced damage. A detailed description of microstructural features covering numerous brittle materials, including ceramics, glass, concrete, metals, polymers and ceramic fibers to help you develop your knowledge of material fracture.

Brittle Failure and Damage of Brittle Materials and Composites outlines the technological progress in this field and the need for reliable systems with high performances to help you advance the development of new structural materials, creating advantages of low density, high resistance to elevated temperatures and aggressive environments, and good mechanical properties.

Chapter 1 : Flaws in materialsChapter 2 : Statistical-probabilistic approaches to brittle fracture: the Weibull model Chapter 3: Statistical – probabilistic theories based on flaw size densityChapter 4: Statistical – probabilistic theories based on flaw strength densityChapter 5 : Effective volume or surface areaChapter 6: Size and stress-state effects on fracture strengthChapter 7 : Determination of statistical parametersChapter 8 : Computation of failure probability: Application to component designChapter 9 : Case studies: Comparison of failure predictions using the Weibull and Multiaxial Elemental Strength Models Chapter 10: Application of statistical-probabilistic approaches to damage and fracture of composite materials and structures
Students, engineers and researchers who are interested in materials science and engineering, most notably fracture and brittle materials.
Jacques Lamon received an award from the Seymour Cray company in 1990 for his work on failure statistics based predictions of brittle failure. In 2006, he was elected Fellow of the American Ceramic Society. In 2007 he received the First Prize of Best Paper Awards from the American Ceramic Society. He has authored one book on the Mechanics of brittle fracture and damage, authored more than 300 technical articles on ceramics reliability, and the thermomechanical behaviour of fibre-reinforced ceramic matrix composites and contributed to/ edited 13 books; 14 conference proceedings, 3 journal special issues and more than 15 testing method standards (CEN) and presented more than 70 invited lectures. HIs current research interests include Thermomechanical behavior of composite materials, modelling of damage, fracture and durability, effects of the environment, multiscale approaches to behavior, fracture and durability and the probabilistic approaches to fracture and damage.
  • The effects of flaw populations on fracture strength
  • The main statistical-probabilistic approaches to brittle fracture
  • The use of these methods for predictions of failure and effects induced by flaw populations
  • The application of these methods to component design
  • The methods of estimation of statistical parameters that define flaw strength distributions
  • The extension of these approaches to damage and failure of continuous fiber reinforced ceramic matrix composites