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In situ thermal dynamics of shallow water corals is affected by tidal patterns and irradiance

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Abstract

We studied the diel variation of in situ coral temperature, irradiance and photosynthetic performance of hemispherical colonies of Porites lobata and branching colonies of Porites cylindrica during different bulk water temperature and tidal scenarios on the shallow reef flat of Heron Island, Great Barrier Reef, Australia. Our study presents in situ evidence that coral tissue surface temperatures can exceed that of the surrounding water under environmental conditions typically occurring during low tide in shallow reef or lagoon environments. Such heating may be a regular occurrence on shallow reef flats, triggered by the combined effects of high irradiance and low water flow characteristic of low Spring tides. At these times, solar heating of corals coincides with times of maximum water temperature and high irradiance, where the slow flow and consequent thick boundary layers impede heat exchange between corals and the surrounding water. Despite similar light-absorbing properties, the heating effect was more pronounced for the hemispherical P. lobata than for the branching P. cylindrica. This is consistent with previous laboratory experiments showing the evidence of interspecific variation in coral thermal environment and may result from morphologically influenced variation in convective heat transfer and/or thermal properties of the skeleton. Maximum coral surface warming did not coincide with maximum irradiance, but with maximum water temperature, well into the low-tide period with extremely low water flow in the partially drained reef flat, just prior to flushing by the rising tide. The timing of low tide thus influences the thermal exposure and photophysiological performance of corals, and the timing of tidally driven coral surface warming could potentially have different physiological impacts in the morning or in the afternoon.

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Acknowledgments

This study was supported by grants from the Australian Research Council (PJR, AWDL) and the Danish Natural Science Research Council (MK). We thank the staff at Heron Island Research Station for excellent technical assistance and logistic support. The research was conducted under the Great Barrier Reef Marine Park Authority permits G05/16166.1, G03/12019.1 and G06/178151.

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Authors and Affiliations

  1. Functional Plant Biology and Climate Change Cluster, Department of Environmental Science, University of Technology Sydney, Broadway, Ultimo, NSW, 2007, Australia

    Isabel M. Jimenez, Anthony W. D. Larkum, Peter J. Ralph & Michael Kühl

  2. Marine Biological Section, Department of Biology, University of Copenhagen, Strandpromenaden 5, 3000, Helsingør, Denmark

    Michael Kühl

Authors
  1. Isabel M. Jimenez
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  2. Anthony W. D. Larkum
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  3. Peter J. Ralph
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  4. Michael Kühl
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Correspondence to Michael Kühl.

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Communicated by K. Bischof.

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Jimenez, I.M., Larkum, A.W.D., Ralph, P.J. et al. In situ thermal dynamics of shallow water corals is affected by tidal patterns and irradiance. Mar Biol 159, 1773–1782 (2012). https://doi.org/10.1007/s00227-012-1968-8

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  • DOI: https://doi.org/10.1007/s00227-012-1968-8

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