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Temperature control on high-resolution SIMS oxygen isotopic compositions in Porites coral skeletons

Authors :
Gangjian Wei
Wenfeng Deng
Yanqiang Zhang
Xi Liu
Guanqiang Cai
Xuefei Chen
Xiaoping Xia
Jieqiong Zou
Ti Zeng
Yangrui Guo
Qing Yang
Source :
Solid Earth Sciences, Vol 6, Iss 2, Pp 129-141 (2021)
Publication Year :
2021
Publisher :
Elsevier, 2021.

Abstract

Oxygen isotope composition (δ18O) in Porites coral skeletons at the micrometer scale has been proposed to be uninfluenced by temperature in previous studies. Considering that temperature is the main controlling factor of coral δ18O at the macro scale, the effect of temperature on the δ18O variations at the micrometer scale should be evaluated carefully. To better understand the climatic and biological significance of high-resolution δ18O in coral skeletons, in situ δ18O values were analyzed in three modern Porites corals from the South China Sea and the Great Barrier Reef by a Cameca IMS 1280-HR secondary ion mass spectrometry (SIMS). A twice vacuum impregnation procedure for sample mount preparation and a subsection calibration method based on multiple controlling points for coral matrix effect correction were used for SIMS analysis. The derived SIMS coral δ18O time series exhibit consistent long-term variations with the monthly δ18O (measured by conventional gas isotope ratios mass spectrometry), monthly Sr/Ca, and daily sea surface temperature, first highlighting the dominant temperature control on micrometer-scale coral δ18O. The 1.5‰ fluctuation amplitude of SIMS coral δ18O at the scales of 400–800 μm can be explained by the combined SST effects of ~10-day variation and day–night fluctuation, whereas the effects of seawater δ18O and growth rate on SIMS coral δ18O seem not dominant. Some abnormally negative δ18O values possibly resulted from the primary ion bombardment on indistinguishable centers of calcification.

Details

Language :
English
Volume :
6
Issue :
2
Database :
OpenAIRE
Journal :
Solid Earth Sciences
Accession number :
edsair.doi.dedup.....9112591ed37360085198128ae3cb662a