Publications des scientifiques de l'IRD

Heindel K., Birgel D., Brunner B., Thiel V., Westphal H., Gischler E., Ziegenbalg S. B., Cabioch Guy, Sjovall P., Peckmann J. (2012). Post-glacial microbialite formation in coral reefs of the Pacific, Atlantic, and Indian Oceans. Chemical Geology, 304, p. 117-130. ISSN 0009-2541.

Titre du document
Post-glacial microbialite formation in coral reefs of the Pacific, Atlantic, and Indian Oceans
Année de publication
2012
Type de document
Article référencé dans le Web of Science WOS:000303098900011
Auteurs
Heindel K., Birgel D., Brunner B., Thiel V., Westphal H., Gischler E., Ziegenbalg S. B., Cabioch Guy, Sjovall P., Peckmann J.
Source
Chemical Geology, 2012, 304, p. 117-130 ISSN 0009-2541
The occurrence of microbialites in post-glacial coral reefs has been interpreted to reflect an ecosystem response to environmental change. The greater thickness of microbialites in reefs with a volcanic hinterland compared to thinner microbial crusts in reefs with a non-volcanic hinterland led to the suggestion that fertilization of the reefal environment by chemical weathering of volcanic rocks stimulated primary productivity and microbialite formation. Using a molecular and isotopic approach on reef-microbialites from Tahiti (Pacific Ocean), it was recently shown that sulfate-reducing bacteria favored the formation of microbial carbonates. To test if similar mechanisms induced microbialite formation in other reefs as well, the Tahitian microbialites are compared with similar microbialites from coral reefs off Vanuatu (Pacific Ocean), Belize (Caribbean Sea, Atlantic Ocean), and the Maldives (Indian Ocean) in this study. The selected study sites cover a wide range of geological settings, reflecting variable input and composition of detritus. The new lipid biomarker data and stable sulfur isotope results confirm that sulfate-reducing bacteria played an intrinsic role in the precipitation of microbial carbonate at all study sites, irrespective of the geological setting. Abundant biomarkers indicative of sulfate reducers include a variety of terminally-branched and mid chain-branched fatty acids as well as mono-O-alkyl glycerol ethers. Isotope evidence for bacterial sulfate reduction is represented by low delta S-34 values of pyrite (-43 to 42 parts per thousand) enclosed in the microbialites and, compared to seawater sulfate, slightly elevated delta S-34 and delta O-18 values of carbonate-associated sulfate (21.9 to 22.2 parts per thousand. and 11.3 to 12.4 parts per thousand, respectively). Microbialite formation took place in anoxic micro-environments, which presumably developed through the fertilization of the reef environment and the resultant accumulation of organic matter including bacterial extracellular polymeric substances (EPS), coral mucus, and marine snow in cavities within the coral framework. ToF-SIMS analysis reveals that the dark layers of laminated microbialites are enriched in carbohydrates, which are common constituents of EPS and coral mucus. These results support the hypothesis that bacterial degradation of EPS and coral mucus within microbial mats favored carbonate precipitation. Because reefal microbialites formed by similar processes in very different geological settings, this comparative study suggests that a volcanic hinterland is not required for microbialite growth. Yet, detrital input derived from the weathering of volcanic rocks appears to be a natural fertilizer, being conductive for the growth of microbial mats, which fosters the development of particularly abundant and thick microbial crusts.
Plan de classement
Géologie et formations superficielles [064]
Localisation
Fonds IRD [F B010055847]
Identifiant IRD
fdi:010055847
Contact