Structure and palaeoenvironmental implications of inter-branch coenosteum-rich skeleton in corymbose Acropora species

Coral reefs provide an increasingly important archive of palaeoclimate data that can be used to constrain climate model simulations. Reconstructing past environmental conditions may also provide insights into the potential of reef systems to survive changes in the Earth’s climate. Reef-based palaeoc...

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Bibliographic Details
Published in:Coral reefs 2015-03, Vol.34 (1), p.201-213
Main Authors: Sadler, J., Webb, G. E., Nothdurft, L. D.
Format: Article
Language:English
Subjects:
Acropora
Archives & records
Biomedical and Life Sciences
Climate models
Coral reefs
Environmental conditions
Freshwater & Marine Ecology
Life Sciences
Marine biology
Marine ecology
Microstructure
Oceanography
Paleoclimate
Paleoclimate science
Porites
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Summary:Coral reefs provide an increasingly important archive of palaeoclimate data that can be used to constrain climate model simulations. Reconstructing past environmental conditions may also provide insights into the potential of reef systems to survive changes in the Earth’s climate. Reef-based palaeoclimate reconstructions are predominately derived from colonies of massive Porites , with the most abundant genus in the Indo-Pacific— Acropora —receiving little attention owing to their branching growth trajectories, high extension rates and secondary skeletal thickening. However, inter-branch skeleton (consisting of both coenosteum and corallites) near the bases of corymbose Acropora colonies holds significant potential as a climate archive. This region of Acropora skeleton is atypical, having simple growth trajectories with parallel corallites, approximately horizontal density banding, low apparent extension rates and a simple microstructure with limited secondary thickening. Hence, inter-branch skeleton in Acropora bears more similarities to the coralla of massive corals, such as Porites , than to traditional Acropora branches. Cyclic patterns of Sr/Ca ratios in this structure suggest that the observed density banding is annual in nature, thus opening up the potential to use abundant corymbose Acropora for palaeoclimate reconstruction.
ISSN:0722-4028
1432-0975
DOI:10.1007/s00338-014-1228-0