Coral Community Adaptability to Environmental Change at the Scales of Regions, Reefs and Reef Zones

Coral Community Adaptability to Environmental Change at the Scales of Regions, Reefs and Reef Zones

Projected global increases in temperature, sea level, storminess and atmospheric carbon dioxide ( CO2) are likely to cause changes in reef coral communities which the present human generation will view as deleterious. It is likely coral community trajectories will be influenced as much by the reduct...

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Bibliographic Details
Published in:American zoologist Vol. 39; no. 1; pp. 66 - 79
Main Author: DONE, TERENCE J.
Format: Journal Article
Language:English
Published: Society for Integrative and Comparative Biology 01-02-1999
Society for Integrative and Comparative Biology(SICB)
Subjects:
Acclimatization
Algae
Anthozoa
Communities
Coral Adaptation and Acclimatization: A Most Ingenious Paradox
Coral reef biology
Coral reef ecology
Coral reefs
Coral reefs and islands
Coralline algae
Corals
Environmental aspects
Global environmental change
International community
Marine
Marine ecology
Marine ecosystems
Reefs
Starfish
United States
World Oceans
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Summary:Projected global increases in temperature, sea level, storminess and atmospheric carbon dioxide ( CO2) are likely to cause changes in reef coral communities which the present human generation will view as deleterious. It is likely coral community trajectories will be influenced as much by the reduction in intervals between extreme events as the projected increases in means of environmental parameters such as temperature, atmospheric CO2and sea-level. Depressed calcification rates in corals caused by reduced aragonite saturation state of water may increase vulnerability of corals to storms. Moreover, reduction in intervals between storms and other extreme events causing mass mortality in corals (coral predators, diseases, bleaching) are likely to more frequently "set back" reef coral communities to early successional stages or alternate states characterized by non-calcifying benthos (plants, soft corals, sponges). The greater the area and the longer the duration of dominance of putative "coral/coralline algae" zones of coral reefs by non-calcifying stages, the less will be the reef's capacity to accrete limestone bulk locked up in the big skeletal units of late successional stages (i.e., very large old corals). Averaged over decades to centuries, the effects of such changes on the coral community's carrying capacity for other biota such as fish are unpredictable. A "shifting steady-state mosaic" null model may provide a useful conceptual tool for defining a baseline and tracking changes from that baseline through time.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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ISSN:0003-1569
2162-4445
DOI:10.1093/icb/39.1.66