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First published online June 15, 2007
Journal of Experimental Biology 210, 2213-2230 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.001560

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Review

Techniques for predicting the lifetimes of wave-swept macroalgae: a primer on fracture mechanics and crack growth

Katharine J. Mach^1,*, Drew V. Nelson² and Mark W. Denny¹

¹ Hopkins Marine Station of Stanford University, Pacific Grove, CA 93950, USA
² Department of Mechanical Engineering, Stanford University, Stanford, CA 94305, USA

^* Author for correspondence (e-mail: mach{at}stanford.edu)

Accepted 8 April 2007

Biomechanical analyses of intertidal and shallow subtidal seaweeds have elucidated ways in which these organisms avoid breakage in the presence of exceptional hydrodynamic forces imposed by pounding surf. However, comparison of algal material properties to maximum hydrodynamic forces predicts lower rates of breakage and dislodgment than are actually observed. Why the disparity between prediction and reality? Most previous research has measured algal material properties during a single application of force, equivalent to a single wave rushing past an alga. In contrast, intertidal macroalgae may experience more than 8000 waves a day. This repeated loading can cause cracks – introduced, for example, by herbivory or abrasion – to grow and eventually cause breakage, yet fatigue crack growth has not previously been taken into account. Here, we present methods from the engineering field of fracture mechanics that can be used to assess consequences of repeated force imposition for seaweeds. These techniques allow quantification of crack growth in wave-swept macroalgae, a first step towards considering macroalgal breakage in the realistic context of repeated force imposition. These analyses can also be applied to many other soft materials.

Key words: fracture mechanics, breakage, fatigue, intertidal, macroalgae, seaweed, biomechanics

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