Inorganic carbon system dynamics in landfast Arctic sea ice during the early‐melt period

Brown, Kristina A.; Miller, Lisa A.; Mundy, C. J.; Papakyriakou, Tim; François, Roger; Gosselin, Michel; Carnat, Gauthier; Swystun, Kyle; Tortell, Philippe D.

doi:10.1002/2014jc010620

Cited by 37 publications

(44 citation statements)

References 64 publications

(131 reference statements)

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“…Peak ice algae Chl a concentrations in that study were relatively low (~20 mg/m 2 ), but there was a distinct pycnocline at ~50‐m depth, separating the polar mixed layer from underlying Pacific water. Conversely, Brown et al () saw no impact of ice algae on p CO 2sw in the water column through the peak of an intense bottom ice algae bloom near Resolute Bay, Nunavut. Ice algae concentrations in that study were much higher (max ~80 mg/m 2 ), but the water column in that region is typically mixed to the bottom (~150 m) due to strong tidally driven currents (Mundy et al, ).…”

Section: Discussionmentioning

confidence: 96%

Response of the Arctic Marine Inorganic Carbon System to Ice Algae and Under‐Ice Phytoplankton Blooms: A Case Study Along the Fast‐Ice Edge of Baffin Bay

et al. 2019

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Past research in seasonally ice‐covered Arctic seas has suggested that ice algae play a role in reducing dissolved inorganic carbon (DIC) during spring, preconditioning surface waters to low dissolved CO2 (pCO2sw), and uptake of atmospheric CO2 during the ice‐free season. The potential role of under‐ice phytoplankton blooms on DIC and pCO2sw has not often been considered. In this study we examined the inorganic carbon system beneath landfast sea ice starting midway through a bottom ice algae bloom and concluding in the early stages of an under‐ice phytoplankton bloom. During most of the ice algae bloom we observed a slight increase in DIC/pCO2sw in surface waters, as opposed to the expected reduction. Biomass calculations confirm that the role of ice algae on DIC/pCO2sw in the study region were minor and that this null result may be widely applicable. During snow melt, we observed an under‐ice phytoplankton bloom (to 10 mg/m3 Chl a) that did reduce DIC and pCO2sw. We conclude that under‐ice phytoplankton blooms are an important biological mechanism that may predispose some Arctic seas to act as a CO2 sink at the time of ice breakup. We also found that pCO2sw was undersaturated at the study location even at the beginning of our sampling period, consistent with several other studies that have measured under‐ice pCO2sw in late winter or early spring. Finally, we present the first measurements of carbonate saturation states for this region, which may be useful for assessing the vulnerability of a local soft‐shelled clam fishery to ocean acidification.

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Section: Discussionmentioning

confidence: 96%

Response of the Arctic Marine Inorganic Carbon System to Ice Algae and Under‐Ice Phytoplankton Blooms: A Case Study Along the Fast‐Ice Edge of Baffin Bay

et al. 2019

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“…The reference ice concentration is set at 400 mmol C/m 3 , based on observed values of DIC for first‐year landfast sea ice near Resolute (generally in the range of 300–500 mmol C/m 3 ; cf. Brown et al, ; Geilfus et al, ). During ice formation, the average DIC concentration of seawater from which the ice is formed is near 2,100 mmol C/m 3 (Brown et al, ), and hence,

{DIC}_{SW}^{ref}

is set at 2,100 mmol C/m 3 .…”

Section: Methodsmentioning

confidence: 99%

“…In the polar oceans, ice cover further complicates the exchanges. Modelers have conventionally treated ice as an inert barrier to the exchange of CO 2 , but recent field work has shown that the growth and melt of sea ice can have a substantial impact on the transport of dissolved inorganic carbon (DIC) and total alkalinity (TA) in the surface polar oceans (e.g., Brown et al, ; Delille et al, ; Geilfus et al ; Miller, Carnat, et al, ; Miller, Papakyriakou, et al, ; Nomura et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…To determine model parameters and assess performance, we use observations near Resolute Passage in the Canadian Arctic Archipelago (CAA). The location was chosen for this 1‐D study because it has been the site of multiple field campaigns to measure inorganic carbon fluxes and carbonate chemical properties above, in, and below the sea ice in the area (notably Brown et al, ; Geilfus et al, ). This location also has a nearby meteorological station from which atmospheric forcing data were obtained (Environment Canada, http://climate.weather.gc.ca/).…”

Section: Introductionmentioning

confidence: 99%

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A Model‐Based Analysis of Physical and Biogeochemical Controls on Carbon Exchange in the Upper Water Column, Sea Ice, and Atmosphere in a Seasonally Ice‐Covered Arctic Strait

et al. 2018

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In this study, we consider a 1-D model incorporating both sea ice and pelagic systems in order to assess the importance of various processes on the vertical transport and exchange of carbon in the seasonally ice-covered marine Arctic. The model includes a coupled ice-ocean ecosystem, a parameterization of ikaite precipitation and dissolution, a formulation for ice-air carbon exchange, and a formulation for brine rejection and freshwater dilution of dissolved inorganic carbon (DIC) and total alkalinity (TA) associated with ice growth and melt. Sensitivity analyses illustrate that (1) the pelagic ecosystem accounts for more than half of the net ocean carbon uptake, but ice algae have little effect on the air-sea exchange in the standard run;(2) inclusion of ikaite precipitation and dissolution do not strongly affect the net ocean carbon uptake for concentrations within the observed range but can become important for larger concentrations; (3) varying DIC and TA in the ice by equal amounts, or varying brine deposition depth, does not affect the net ocean carbon uptake, because the coincident changes in TA and DIC concentrations at the sea surface serve to counteract one another with respect to sea surface pCO 2 ; and (4) the proportions of carbon released to the water column (versus to the atmosphere) during ice growth and melt are important quantities to constrain in order to determine the contribution of the combined ice-ocean system to oceanic uptake of atmospheric carbon. Plain Language SummaryCarbon dioxide is being taken up by the global oceans, especially at the poles. Although sea ice has been treated as a barrier to air-sea exchange of gases, recent observations have shown that it is not so simple. This study uses a model to represent loss, gain, and movement of inorganic carbon due to sea ice growth and melt, ice and water column ecosystems, and air-sea exchange in the open-water season. Results from this study indicate that the ecosystem is a major player in the uptake of carbon dioxide by the Arctic Ocean and that fundamental processes relating to the sea ice need to be further studied, in particular, (a) how ice (low in inorganic carbon) is created from seawater (high in inorganic carbon) and (b) the formation of carbon-containing crystals in sea ice.

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“…The overall difference between photosynthesis and respiration represents net community production and describes whether sea ice may be considered as a net autotrophic (O 2 gain) or heterotrophic (O 2 loss) system [Codispoti et al, 2013]. The productive state of the biological community affects gas fluxes between the ice and ocean [Brown et al, 2015], as well as carbon cycling within the Arctic marine system [Matrai and Apollonio, 2013;Michel et al, 2015].…”

Section: Introductionmentioning

confidence: 99%

Net community production in the bottom of first‐year sea ice over the Arctic spring bloom

Campbell

Mundy

Gosselin

et al. 2017

Geophysical Research Letters

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The balance of photosynthesis and respiration by organisms like algae and bacteria determines whether sea ice is net heterotrophic or autotrophic. In turn this clarifies the influence of microbes on atmosphere‐ice‐ocean gas fluxes and their contribution to the trophic system. In this study we define two phases of the spring bloom based on bottom ice net community production and algal growth. Phase I was characterized by limited algal accumulation and low productivity, which at times resulted in net heterotrophy. Greater productivity in Phase II drove rapid algal accumulation that consistently produced net autotrophic conditions. The different phases were associated with seasonal shifts in light availability and species dominance. Results from this study demonstrate the importance of community respiration on spring productivity, as respiration rates can maintain a heterotrophic state independent of algal growth. This challenges previous assumptions of a fully autotrophic sea ice community during the ice‐covered spring.

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Inorganic carbon system dynamics in landfast Arctic sea ice during the early‐melt period

Cited by 37 publications

References 64 publications

Response of the Arctic Marine Inorganic Carbon System to Ice Algae and Under‐Ice Phytoplankton Blooms: A Case Study Along the Fast‐Ice Edge of Baffin Bay

Response of the Arctic Marine Inorganic Carbon System to Ice Algae and Under‐Ice Phytoplankton Blooms: A Case Study Along the Fast‐Ice Edge of Baffin Bay

A Model‐Based Analysis of Physical and Biogeochemical Controls on Carbon Exchange in the Upper Water Column, Sea Ice, and Atmosphere in a Seasonally Ice‐Covered Arctic Strait

Net community production in the bottom of first‐year sea ice over the Arctic spring bloom

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