Materials Science - General & Miscellaneous, Mechanical Engineering - General & Miscellaneous, Mechanical Physics - Structural, Fracture Mechanics, Technology - General & Miscellaneous, Structural Engineering - General & Miscellaneous, Electronics - Micro

Fractography: Observing, Measuring and Interpreting Fracture Surface Topography

Name: Fractography: Observing, Measuring and Interpreting Fracture Surface Topography
Author: Derek Hull
ISBN: 9780521646840

by Derek Hull

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Overview

Fracture surfaces are produced when a solid breaks. The appearance of the surface, particularly the topography, depends on both the type of material broken and the conditions under which it was broken, such as stress, temperature, or environment. Fractography describes the ways of studying these surfaces. Coverage includes all the information needed to understand the deformation and fracture in all types of solids and to interpret the topographical features in terms of the microstructure and the way it was tested. It also provides details on how to design clear and unambiguous experiments that involve many aspects of fracture in a wide range of solids. This book is an invaluable resource for undergraduate and graduate students, as well as researchers, industrial scientists, engineers, and anyone with an interest in materials science.

Synopsis

Fracture surfaces are produced by breaking a solid. The appearance of the surface, particularly the topography, depends on the type of material - metal, polymer, ceramic, biomaterial, composite, rock - and on the conditions under which it was broken - stress (tensile, shear, creep, fatigue, impact), temperature, environment (air, water, oil, acid), etc. This 1999 book describes ways of studying the surface topography, and the interpretation of the topographical features in terms of the microstructure and the way it was tested. Fractography has numerous applications in a range of materials, and is particularly relevant in materials science and to inter-disciplinary subjects involving materials science, including physics, chemistry, engineering, biomimetics, earth sciences, biology and archaeology. This book provides the basis for an understanding of deformation and fracture in all solids, for interpreting fracture surface topography, and for the design of clear and unambiguous experiments involving many aspects of fracture in a wide range of solids.