Abstract
Abstract. The oxygen and hydrogen isotopic compositions of water in fluid inclusions in speleothems are important hydroclimate proxies because they provide information on the isotopic compositions of rainwater in the past. Moreover, because isotopic differences between fluid inclusion water and the host calcite provide information on the past isotopic fractionation factor, they are also useful for quantitative estimation of past temperature changes. The oxygen isotope ratio of inclusion water (δ18Ofi), however, may be affected by isotopic exchange between the water and the host carbonate. Thus, it is necessary to estimate the bias caused by this postdepositional effect for precise reconstruction of paleotemperatures. Here, we evaluate the isotopic exchange reaction between inclusion water and host calcite based on a laboratory experiment involving a natural stalagmite. Multiple stalagmite samples cut from the same depth interval were heated at 105 ∘C in the laboratory from 0 to 80 h. Then, the isotopic compositions of the inclusion water were measured. In the 105 ∘C heating experiments, the δ18Ofi values increased from the initial value by 0.7 ‰ and then remained stable after ca. 20 h. The hydrogen isotope ratio of water showed no trend in response to the heating experiments, suggesting that the hydrogen isotopic composition of fluid inclusion water effectively reflects the composition of past drip water. We then evaluated the process behind the observed isotopic variations using a partial equilibration model. The experimental results are best explained by the assumption that a thin CaCO3 layer surrounding the inclusion reacted with the water. The amount of CaCO3 that reacted with the water is equivalent to 2 % of the water inclusions in molar terms. These results suggest that the magnitude of the isotopic exchange effect has a minor influence on paleotemperature estimates for Quaternary climate reconstructions.
Highlights
Speleothems have provided invaluable terrestrial climate records over historical (e.g., Zhang et al, 2008) and glacial– interglacial (e.g., Wang, 2001; Wang et al, 2017) timescales
The results suggest that the observed increase in δ18Ofi values in the 105 ◦C heating experiment is caused by the oxygen isotopic exchange between inclusion water and the surrounding calcite
The isotopic compositions of inclusion water are shown as a deviation from the initial value ( δ18Ofi and δDfi)
Summary
Speleothems have provided invaluable terrestrial climate records over historical (e.g., Zhang et al, 2008) and glacial– interglacial (e.g., Wang, 2001; Wang et al, 2017) timescales. Among multiple climate proxies in speleothems (Fairchild et al, 2006), the stable oxygen isotope ratio of CaCO3 (δ18Oca) is the most widely used hydroclimate proxy. The indeterminate nature of δ18Oca interpretation is related to the fact that the δ18Oca values are mainly controlled by two factors: the temperature in the cave and the annual mean δ18O value of the rainwater. To overcome this ambiguity, the isotopic compositions of water in fluid inclusions in stalagmites have been regarded as important proxies (Schwarcz et al, 1976; McDermott, 2004).
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