The mechanics of foams: basic results

Lorna J. Gibson; Michael F. Ashby

doi:10.1017/CBO9781139878326.007

Chapter 5 - The mechanics of foams: basic results

Published online by Cambridge University Press: 05 August 2014

Lorna J. Gibson and

Michael F. Ashby

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Lorna J. Gibson: Affiliation:
Massachusetts Institute of Technology
Michael F. Ashby: Affiliation:
University of Cambridge

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Introduction and synopsis

Almost any solid can be foamed. Techniques now exist for making three-dimensional cellular solids out of polymers, metals, ceramics and even glasses. Manmade foams, manufactured on a large scale, are used for absorbing the energy of impacts (in packaging and crash protection) and in lightweight structures (in the cores of sandwich panels, for instance); their efficient use requires a detailed understanding of their mechanical behaviour. Even when the primary use is not mechanical – when the foam is used for thermal insulation, or flotation, or as a filter, for example – the strength and fracture behaviour are still important. Nature, too, uses cellular materials on a large scale. Often the primary function is mechanical, as with wood (to support the tree) or cancellous bone (to give the animal a light, stiff, frame). In other cases it may not be: the shape of the cells in leaf and stalk, or in cork and sponge, may be dictated by the need to optimize fluid transport or thermal insulation or surface area, but even here the mechanical properties are important because the cells still support the structure. And there is the consuming subject of food. Bread – The Staff of Life – and many other starch-based foods are foams. Foaming with yeast or CO2 gives the tough, leathery starch a crisp crunchiness which is attractive to bite on and chew (mechanical operations); but it also makes transporting the product more difficult because its crushing strength is reduced.

Type: Chapter
Information: Cellular Solids
Structure and Properties
, pp. 175 - 234

DOI: https://doi.org/10.1017/CBO9781139878326.007 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 1997

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Chapter 5 - The mechanics of foams: basic results

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