Reconsidering the role of carbonate ion concentration in calcification by marine organisms

Marine organisms precipitate 0.52.0 Gt of carbon as calcium carbonate (CaCO 3 ) every year with a profound impact on global biogeochemical element cycles. Biotic calcification relies on calcium ions (Ca 2+ ) and usually on bicarbonate ions (HCO 3 − ) as CaCO 3 substrates and can be inhibited by high...

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Bibliographic Details
Published in:Biogeosciences
Main Author: Bach, LT
Format: Article in Journal/Newspaper
Language:English
Published: Copernicus GmbH 2015
Subjects:
Earth Sciences
Oceanography
Biological Oceanography
Ocean acidification
Online Access:https://doi.org/10.5194/bg-12-4939-2015
http://ecite.utas.edu.au/133566
Description
Summary:Marine organisms precipitate 0.52.0 Gt of carbon as calcium carbonate (CaCO 3 ) every year with a profound impact on global biogeochemical element cycles. Biotic calcification relies on calcium ions (Ca 2+ ) and usually on bicarbonate ions (HCO 3 − ) as CaCO 3 substrates and can be inhibited by high proton (H + ) concentrations. The seawater concentration of carbonate ions (CO 3 2− ) and the CO 3 2− -dependent CaCO 3 saturation state (Ω CaCO 3 ) seem to be irrelevant in this production process. Nevertheless, calcification rates and the success of calcifying organisms in the oceans often correlate surprisingly well with these two carbonate system parameters. This study addresses this dilemma through the rearrangement of carbonate system equations which revealed an important proportionality between [CO 3 2− ] or Ω CaCO 3 and the ratio of [HCO 3 − ] to [H + ]. Due to this proportionality, calcification rates will always correlate as well with [HCO 3 − ] / [H + ] as they do with [CO 3 2− ] or Ω CaCO 3 when temperature, salinity, and pressure are constant. Hence, [CO 3 2− ] and Ω CaCO 3 may simply be very good proxies for the control by [HCO 3 − ] / [H + ], where [HCO 3 − ] serves as the inorganic carbon substrate and [H + ] functions as a calcification inhibitor. If the "substrateinhibitor ratio" (i.e., [HCO 3 − ] / [H + ]) rather than [CO 3 2− ] or Ω CaCO 3 controls biotic CaCO 3 formation, then some of the most common paradigms in ocean acidification research need to be reviewed. For example, the absence of a latitudinal gradient in [HCO 3 − ] / [H + ] in contrast to [CO 3 2− ] and Ω CaCO 3 could modify the common assumption that high latitudes are affected most severely by ocean acidification.

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