Cibicidodes Pachyderma B/Ca as a Shalow Water Carbonate Saturation State Proxy
Abstract
Since the industrial revolution, the oceans have absorbed about 25% of anthropogenic CO2 emissions to the atmosphere, leading to a decrease in seawater pH (termed ocean acidification: OA) as well as many associated effects, including decreased saturation states. Assessment of the effects of OA on marine ecosystems is presently based on <50 years of observations. Reconstructions of past seawater chemistry and its impact on biota over much longer time scales can provide essential context for likely future consequences of OA. Reliable oceanic paleo-proxies for influential chemical variables such as pH and carbonate saturation state are crucial components for examining ancient environments affected by OA. Addition of CO2 to seawater leads to not only decreases in seawater pH and saturation state, but also the extent to which boron (B) is incorporated into CaCO3 during biotic calcification. Consequently, the abundance of B in calcite could reflect pH and/or saturation state of the water in which calcification occurred. Recent studies indicate a linear relationship between the ratio of boron to calcium (B/Ca) in benthic foraminifera shells ( Cibicidoides wuellerstorfi, C. mundulus) and the degree of carbonate saturation (Δ[CO32-]), defined as a difference between [CO32-]in situ and [CO32-]saturation. However, the observed relationship between B/Ca and Δ[CO32-] was only established for depths >1000m. Thus, since OA most immediately affects the upper 1000 m of the water column, a reliable shallow water (<1000 m) carbonate chemistry proxy is desirable. We are testing the utility of B/Ca in Cibicidoides pachyderma as a shallow water Δ[CO32-] proxy. C. pachyderma is an epibenthic species and therefore records the composition of bottom, rather than interstitial, waters. It usually inhabits depths between 200 and 1000 m, and is a common species in the Gulf of Mexico. The gently sloping West Florida Shelf (WFS) is an excellent setting for this kind of study as it provides a full range of depths habitable by C.pachyderma. Nine surface sediment samples were collected along a 150-1400 m depth transect across the WFS. Bottom water pH along the transect ranged between 7.82 and 8.12, corresponding to Δ[CO32-] values between 35 and 200 μmol/kg. Preliminary B/Ca data range between 109 and 174 μmol/mol and display high variability. Our results suggest that WFS bottom water chemistry may be intermittently affected by phenomena such as eutrophication-induced hypoxia or boundary layer differences between the lower water column and the sediment-water interface. Additional B/Ca and bottom water measurements are planned to characterize the relationship between C.pachyderma B/Ca and Δ[CO32-], and extend global benthic foraminifera B/Ca calibrations to depths shallower than 1000 m.
- Publication:
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AGU Fall Meeting Abstracts
- Pub Date:
- December 2012
- Bibcode:
- 2012AGUFM.B21C0366W
- Keywords:
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- 4924 PALEOCEANOGRAPHY / Geochemical tracers;
- 4930 PALEOCEANOGRAPHY / Greenhouse gases;
- 4944 PALEOCEANOGRAPHY / Micropaleontology;
- 4994 PALEOCEANOGRAPHY / Instruments and techniques