The hydrodynamic effects of shape and size change during reconfiguration of a flexible macroalga

Rocky intertidal organisms experience large hydrodynamic forces due to high water velocities created by breaking waves. Flexible organisms, like macroalgae, often experience lower drag than rigid organisms because their shape and size change as velocity increases. This phenomenon, known as reconfigu...

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Veröffentlicht in:	Journal of experimental biology 2006-05, Vol.209 (Pt 10), p.1894-1903
Hauptverfasser:	Boller, Michael L, Carrington, Emily
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Sprache:	eng
Schlagworte:	Adaptation, Physiological Biomechanical Phenomena Chondrus crispus Environment Eukaryota - growth & development Water
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container_title	Journal of experimental biology
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creator	Boller, Michael L Carrington, Emily
description	Rocky intertidal organisms experience large hydrodynamic forces due to high water velocities created by breaking waves. Flexible organisms, like macroalgae, often experience lower drag than rigid organisms because their shape and size change as velocity increases. This phenomenon, known as reconfiguration, has been previously quantified as Vogel's E, a measure of the relationship between velocity and drag. While this method is very useful for comparing reconfiguration among organisms it does not address the mechanisms of reconfiguration, and its application to predicting drag is problematic. The purpose of this study was twofold: (1) to examine the mechanisms of reconfiguration by quantifying the change in shape and size of a macroalga in flow and (2) to build a mechanistic model of drag for reconfiguring organisms. Drag, frontal area and shape of the intertidal alga Chondrus crispus were measured simultaneously in a recirculating flume at water velocities from 0 to approximately 2 m s(-1). Reconfiguration was due to two separate mechanisms: whole-alga realignment (deflection of the stipe) at low velocities (
doi_str_mv	10.1242/jeb.02225
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Reconfiguration was due to two separate mechanisms: whole-alga realignment (deflection of the stipe) at low velocities (<0.2 m s(-1)) and compaction of the crown (reduction in frontal area and change in shape) at higher velocities. Change in frontal area contributed more to drag reduction than change in drag coefficient. Drag coefficient and frontal area both decrease exponentially with increasing water velocity, and a mechanistic model of drag was developed with explicit functions to describe these changes. 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source	MEDLINE; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; Company of Biologists
subjects	Adaptation, Physiological Biomechanical Phenomena Chondrus crispus Environment Eukaryota - growth & development Water
title	The hydrodynamic effects of shape and size change during reconfiguration of a flexible macroalga
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