Marine Mussels. Elizabeth Gosling
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Название: Marine Mussels

Автор: Elizabeth Gosling

Издательство: John Wiley & Sons Limited

Жанр: Техническая литература

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isbn: 9781119293934

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СКАЧАТЬ identify temperature drops in a datalogger time series and calculate daily and monthly summary statistics of temperature. They concluded that ESL parameters provide a useful metric for comparing the effects of wave action on immersion patterns within sites. A sensor has now been designed to measure wave forces and wave heights on a time and size scale appropriate for organisms inhabiting the surf zone of rocky intertidal shores. The instrument is capable of continuous deployments for a duration of several months. The sensor/logger package consists of a three‐axis force transducer connected to a resin model of a mussel (M. edulis), a custom‐made datalogger in a waterproof housing and their respective communication cables (details in Lima et al. 2011).

      One might also expect that when higher water velocities are encountered, mussels will produce more byssal threads to increase strength of attachment. However, this is not the case, as shown by Moeser et al. (2006), who reported that in flume experiments mussels (M. edulis) significantly reduced thread production at water velocities above 15 cm s−1 (but see contrary findings in Zardi et al. 2007b). Similar findings were reported in a subsequent study on four mussel species, M. trossulus, M. galloprovincialis, M. californianus and Modiolus modiolus by Carrington et al. (2008). For all four species, velocities above 20 cm s−1 visibly hindered the mussel’s ability to extend its foot beyond the margin of the shell, a posture that must be held for several minutes in order to mold and attach a new thread to the substrate. Even in the exposed shore species, M. californianus, velocities above 30 cm s−1 precluded thread formation. Altogether, this study established 50 cm s−1 as a reasonable threshold limiting byssal thread production in solitary mussels. The authors found that flow was greatly ameliorated within mussel aggregations, ranging from 0.1 to 10% of free‐stream velocity, thus explaining why mussels can persist on shores with water flows in excess of their physiological limits.

      Wave action also has a controlling influence on mussel bed communities by causing dislodgement through lift and drag, especially when mussel beds are dense and firmly packed, as on the majority of wave‐exposed shores (Figure 3.1). When dislodgement occurs, new space is created for colonisation. The risk of dislodgement in M. edulis increases with flow speed and mussel size and decreases with mussel tenacity or attachment strength; the latter varies twofold during the year, but this cycle is not aligned precisely with seasonal patterns of wave velocity (Carrington 2002). In a subsequent study, mussels (M. galloprovincialis) on rocky shores were found to allocate resources to reduce risk of dislodgement (smaller, thicker shell, stronger byssal threads) instead of promoting growth and reproduction (Babarro & Carrington 2013).

Photos depict a quadrat from Black Point, Rhode Island Sound, United States, taken on (top) October 3 and (bottom) October 21, 2001.

      Source: From Carrington et al. (2009). Reproduced with permission from John Wiley and Sons.

Schematic illustration of summary of mussel dislodgment in Rhode Island, 2001–2003.

      Source: From Carrington et al. (2009). Reproduced with permission СКАЧАТЬ