Dissolution of Carbonate Sediments Under Rising pCO2 and Ocean Acidification: Observations from Devil’s Hole, Bermuda
Dissolution of Carbonate Sediments Under Rising pCO2 and Ocean Acidification: Observations from Devil’s Hole, Bermuda
Rising atmospheric pCO2 and ocean acidification originating from human activities could result in increased dissolution of metastable carbonate minerals in shallow-water marine sediments. In the present study, in situ dissolution of carbonate sedimentary particles in Devil’s Hole, Bermuda, was observed during summer when thermally driven density stratification restricted mixing between the bottom water and the surface mixed layer and microbial decomposition of organic matter in the subthermocline layer produced pCO2 levels similar to or higher than those levels anticipated by the end of the 21st century. Trends in both seawater chemistry and the composition of sediments in Devil’s Hole indicate that Mg-calcite minerals are subject to selective dissolution under conditions of elevated pCO2. The derived rates of dissolution based on observed changes in excess alkalinity and estimates of vertical eddy diffusion ranged from 0.2 mmol to 0.8 mmol CaCO3 m?2 h?1. On a yearly basis, this range corresponds to 175–701 g CaCO3 m?2 year?1; the latter rate is close to 50% of the estimate of the current average global coral reef calcification rate of about 1,500 g CaCO3 m?2 year?1. Considering a reduction in marine calcification of 40% by the year 2100, or 90% by 2300, as a result of surface ocean acidification, the combination of high rates of carbonate dissolution and reduced rates of calcification implies that coral reefs and other carbonate sediment environments within the 21st and following centuries could be subject to a net loss in carbonate material as a result of increasing pCO2 arising from burning of fossil fuels.
Climate change, CO2, Ocean acidification, Carbonate minerals, CaCO3 dissolution, Mg-calcite, Coral reef, Calcification
237-264
Andersson, Andreas J.
b07d71e9-2654-40ba-9c69-0775557bf7de
Bates, Nicholas R.
954a83d6-8424-49e9-8acd-e606221c9c57
Mackenzie, Fred T.
02e63726-bde1-4934-93f7-8f2800e44324
September 2007
Andersson, Andreas J.
b07d71e9-2654-40ba-9c69-0775557bf7de
Bates, Nicholas R.
954a83d6-8424-49e9-8acd-e606221c9c57
Mackenzie, Fred T.
02e63726-bde1-4934-93f7-8f2800e44324
Andersson, Andreas J., Bates, Nicholas R. and Mackenzie, Fred T.
(2007)
Dissolution of Carbonate Sediments Under Rising pCO2 and Ocean Acidification: Observations from Devil’s Hole, Bermuda.
Aquatic Geochemistry, 13 (3), .
(doi:10.1007/s10498-007-9018-8).
Abstract
Rising atmospheric pCO2 and ocean acidification originating from human activities could result in increased dissolution of metastable carbonate minerals in shallow-water marine sediments. In the present study, in situ dissolution of carbonate sedimentary particles in Devil’s Hole, Bermuda, was observed during summer when thermally driven density stratification restricted mixing between the bottom water and the surface mixed layer and microbial decomposition of organic matter in the subthermocline layer produced pCO2 levels similar to or higher than those levels anticipated by the end of the 21st century. Trends in both seawater chemistry and the composition of sediments in Devil’s Hole indicate that Mg-calcite minerals are subject to selective dissolution under conditions of elevated pCO2. The derived rates of dissolution based on observed changes in excess alkalinity and estimates of vertical eddy diffusion ranged from 0.2 mmol to 0.8 mmol CaCO3 m?2 h?1. On a yearly basis, this range corresponds to 175–701 g CaCO3 m?2 year?1; the latter rate is close to 50% of the estimate of the current average global coral reef calcification rate of about 1,500 g CaCO3 m?2 year?1. Considering a reduction in marine calcification of 40% by the year 2100, or 90% by 2300, as a result of surface ocean acidification, the combination of high rates of carbonate dissolution and reduced rates of calcification implies that coral reefs and other carbonate sediment environments within the 21st and following centuries could be subject to a net loss in carbonate material as a result of increasing pCO2 arising from burning of fossil fuels.
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Published date: September 2007
Keywords:
Climate change, CO2, Ocean acidification, Carbonate minerals, CaCO3 dissolution, Mg-calcite, Coral reef, Calcification
Organisations:
Ocean Biochemistry & Ecosystems
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Local EPrints ID: 357434
URI: http://eprints.soton.ac.uk/id/eprint/357434
ISSN: 1380-6165
PURE UUID: 4bf59b84-40ea-4a25-b86d-b784f2f41407
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Date deposited: 25 Sep 2013 12:30
Last modified: 14 Mar 2024 14:58
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Author:
Andreas J. Andersson
Author:
Fred T. Mackenzie
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