Abstract
Sulfur and molybdenum trace impurities in speleothems (stalagmites and stalactites) can provide long and continuous records of volcanic activity, which are important for past climatic and environmental reconstructions. However, the chemistry governing the incorporation of the trace element-bearing species into the calcium carbonate phases forming speleothems is not well understood. Our previous work has shown that substitution of tetrahedral oxyanions [XO4]2– (X = S and Mo) replacing [CO3]2– in CaCO3 bulk phases (except perhaps for vaterite) is thermodynamically unfavorable with respect to the formation of competing phases, due to the larger size and different shape of the [XO4]2– tetrahedral anions in comparison with the flat [CO3]2– anions, which implied that most of the incorporation would happen at the surface rather than at the bulk of the mineral. Here, we present an ab initio molecular dynamics study, exploring the incorporation of these impurities at the mineral–water interface. We show that the oxyanion substitution at the aqueous calcite (10.4) surface is clearly favored over bulk incorporation, due to the lower structural strain on the calcium carbonate solid. Incorporation at surface step sites is even more favorable for both oxyanions, thanks to the additional interface space afforded by the surface line defect to accommodate the tetrahedral anion. Differences between sulfate and molybdate substitutions can be mostly explained by the size of the anions. The molybdate oxyanion is more difficult to incorporate in the calcite bulk than the smaller sulfate oxyanion. However, when molybdate is substituted at the surface, the elastic cost is avoided because the oxyanion protrudes out of the surface and gains stability via the interaction with water at the interface, which in balance results in more favorable surface substitution for molybdate than for sulfate. The detailed molecular-level insights provided by our calculations will be useful to understand the chemical basis of S- and Mo-based speleothem records.
Highlights
Paleoclimate reconstructions are essential for understanding modern-day climate change but are hindered by a lack of instrumental environmental records
We have presented an ab initio molecular dynamics (AIMD) investigation of the incorporation of sulfate and molybdate as substitutional impurities in the bulk and surface of calcite
In order to understand the differences between sulfate and molybdate substitution thermodynamics, we need to pay attention to other factors, for example, the partial hydration of the impurity at the calcite surface
Summary
Paleoclimate reconstructions are essential for understanding modern-day climate change but are hindered by a lack of instrumental environmental records. Long and continuous climate reconstructions rely upon geological archives (e.g., marine and lake sediments, trees, and speleothems) of prevailing environmental conditions in the past. Ice cores,[3−5] tree rings,[6] and marine sediments[7] are examples of widely exploited geological archives, which have the potential to capture and preserve geochemical indicators of volcanic activity. These archives hold geochemical proxies in naturally undisturbed states for millennia, allowing for environmental indicators to be matched to specific periods of Earth’s history. Chemical impurities associated with geological and atmospheric conditions following a volcanic eruption can be detected in radiometrically dated subsections of speleothem minerals.[12,13] Prevalence of certain impurities can be indicative of an Received: May 6, 2021 Revised: June 29, 2021 Accepted: July 13, 2021 Published: July 27, 2021
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