C and O isotopes in deep-sea corals (Lophelia pertusa) measured by ion microprobe

Blamart, D.; Rollion-Bard, C.; Cuif, J.P.; Juillet-Leclerc, A.; Lutringer, A.; van Weering, T.; Henriet, J.P.

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C and O isotopes in deep-sea corals (Lophelia pertusa) measured by ion microprobe

Blamart, D.; Rollion-Bard, C.; Cuif, J.P.; Juillet-Leclerc, A.; Lutringer, A.; van Weering, T.; Henriet, J.P. (2003). C and O isotopes in deep-sea corals (Lophelia pertusa) measured by ion microprobe. Erlanger Geol. Abh. Sonderband 4(109): 22

In: Erlanger Geologische Abhandlungen. Institut für Geologie der Universität Erlangen-Nürnberg: Erlangen. ISSN 0071-1160, more

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VLIZ: Open Marine Archive 215198 [ download pdf ]
Document type: Summary

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Marine/Coastal

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Blamart, D. Rollion-Bard, C. Cuif, J.P. Juillet-Leclerc, A.	Lutringer, A. van Weering, T., more Henriet, J.P., more

Abstract

We have determined the d¹⁸O and d¹³C values of azooxanthellate corals (Lophelia pertusa ) at a micrometre scale using an ion microprobe (SIMS-Secondary Ion Mass Spectrometry). Coral skeletons are composed of two different microstructures:

Centres of calcification, and
surrounding fibres.

In Lophelia pertusa centres of calcification are large (50µm) and arranged in lines of centres of calcification. Our results show that centres of calcification in Lophelia pertusa have a restricted range of variation in d¹⁸O (-2.8 ± 0.3‰ (V-PDB)), and a larger range in d¹³C (14.3 to 10.9‰ (V-PDB)). Surrounding skeletal fibres exhibit large isotopic variation both for C and O (up to 12‰), and d¹³C and d¹⁸O are positively correlated. The C and O isotopic compositions of the centre of calcification deviate from this linear trend at the lightest d¹⁸O values of the surrounding fibres. The variation of d¹⁸O at a micrometre scale is probably the result of two processes:

An isotopic equilibrium calcification with at least 1 pH unit variation in the calcification fluid as indicated by direct measurements of coelenteron pH in the coral Galaxea fascicularis (Al-Horani et al., 2003), and
a kinetic fractionation.

The d¹³ apparent disequilibrium in Lophelia pertusa may be the result of mixing between depleted d¹³C metabolic CO₂ (respiration) and DIC coming directly from seawater.

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