Summer carbonate chemistry in the Dalton Polynya, East Antarctica

The carbonate chemistry in the Dalton Polynya in East Antarctica (115123E) was investigated in summer 2014/2015 using high‐frequency underway measurements of CO 2 fugacity ( f CO 2 ) and discrete water column measurements of total dissolved inorganic carbon (TCO 2 ) and total alkalinity. Air‐sea CO...

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Bibliographic Details
Published in:Journal of Geophysical Research: Oceans
Main Authors: Arroyo, MC, Shadwick, EH, Tilbrook, B
Format: Article in Journal/Newspaper
Language:English
Published: Wiley-Blackwell Publishing Inc. 2019
Subjects:
Earth Sciences
Climate change science
Climate change processes
Antarctic
East Antarctica
Antarc*
Antarctica
Antarctica Journal
Ice Shelf
Sea ice
Totten Ice Shelf
ice covered waters
Online Access:https://doi.org/10.1029/2018JC014882
http://ecite.utas.edu.au/143149
Description
Summary:The carbonate chemistry in the Dalton Polynya in East Antarctica (115123E) was investigated in summer 2014/2015 using high‐frequency underway measurements of CO 2 fugacity ( f CO 2 ) and discrete water column measurements of total dissolved inorganic carbon (TCO 2 ) and total alkalinity. Air‐sea CO 2 fluxes indicate this region was a weak net source of CO 2 to the atmosphere (0.7 0.9 mmol C m −2 day −1 ) during the period of observation, with the largest degree of surface water supersaturation (Δ f CO 2 = +45 μatm) in ice‐covered waters near the Totten Ice Shelf (TIS) as compared to the ice‐free surface waters in the Dalton Polynya. The seasonal depletion of mixed‐layer TCO 2 (6 to 51 μmol/kg) in ice‐free regions was primarily driven by sea ice melt and biological CO 2 uptake. Estimates of net community production (NCP) reveal net autotrophy in the ice‐free Dalton Polynya (NCP = 520 mmol C m −2 day −1 ) and weakly heterotrophic waters near the ice‐covered TIS (NCP = −40 mmol C m −2 day −1 ). Satellite‐derived estimates of chlorophyll a (Chl a ) and sea ice coverage suggest that the early summer season in 2014/2015 was anomalous relative to the long‐term (19972017) record, with lower surface Chl a concentrations and a greater degree of sea ice cover during the period of observation; the implications for seasonal primary production and air‐sea CO 2 exchange are discussed. This study highlights the importance of both physical and biological processes in controlling air‐sea CO 2 fluxes and the significant interannual variability of the CO 2 system in Antarctic coastal regions.

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