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Voids in Materials: From Unavoidable Defects to Designed Cellular Materials Gary M. Gladysz and Krishan K. Chawla

Elsevier, 2014 214 pages, $175.00 ISBN 978-0-444-56367-5

Published online by Cambridge University Press:  01 April 2015

Abstract

Type
Other
Copyright
Copyright © Materials Research Society 2015 

The properties of many naturally occurring and manufactured materials are defined by the extent to which they contain voids of various types, shapes, and sizes. The focus of this book is on voids in solid-state materials, including structural materials and biologically inspired hierarchical materials. The target audience is the materials scientist who is a non-expert on porous materials and is interested in an accessible, extended overview of the field.

Unlike many other books on porous materials, which tend to focus on a particular materials class such as polymers where voids play an important role, the authors here introduce and define intentional versus unintentional voids across length scales in multiple classes of materials, including metals, ceramics, polymers, and cellular materials. There is brief discussion of carbon nanotubes, but other nanoporous materials, such as inorganic nanotubes, zeolites, and metal–organic hybrids, are not discussed.

The authors do a good job of highlighting the similarities among voids in these various types of materials and describing the ways in which voids impact their properties. Equations are given throughout, but, as the authors indicate in the preface, the emphasis is on a descriptive rather than a rigorous mathematical presentation. An extensive bibliography is provided so that the interested reader is able to follow up with the source material when greater depth is needed.

The authors next review the methods by which voids are introduced experimentally into materials, fibers, and powders. They further discuss the various ways in which these components can be combined to form composites with a hierarchical porous structure. These materials are distinct from solid-state cellular materials, or foams, which are described in their own chapter. Useful tables are included that list example materials and associated void sizes, along with associated applications and references, which help the reader rapidly navigate the material.

The book closes with a chapter on the applications of materials with voids of different scales and some of the most important methods by which voids are characterized experimentally. Computational materials science is primarily confined to a brief discussion of finite element modeling. This book is recommended to those who desire an accessible, introductory overview to porous materials.

Reviewer: Susan B. Sinnottof the University of Florida, USA.