Sea ice contribution to the air–sea CO&lt;sub&gt;2&lt;/sub&gt; exchange in the Arctic and Southern Oceans

Abstract. Eddy covariance observations of CO 2 fluxes were conducted during March-April 2012 in a temporally sequential order for 8, 4 and 30 days, respectively, at three locations on fast sea ice and on newly formed polynya ice in a coastal fjord environment in northeast Greenland. CO 2 fluxes at the sites characterized by fast sea ice (ICEI and DNB) were found to increasingly reflect periods of strong outgassing in accordance with the progression of springtime warming and the occurrence of strong wind events: F ICE1 CO 2 = 1.73 ± 5 mmol m −2 day −1 and F DNB CO 2 = 8.64 ± 39.64 mmol m −2 day −1 , while CO 2 fluxes at the polynya site (POLYI) were found to generally reflect uptake F POLY1 CO 2 = −9.97 ± 19.8 mmol m −2 day −1 . Values given are the mean and standard deviation, and negative/positive values indicate uptake/outgassing, respectively. A diurnal correlation analysis supports a significant connection between site energetics and CO 2 fluxes linked to a number of possible thermally driven processes, which are thought to change the pCO 2 gradient at the snow-ice interface. The relative influence of these processes on atmospheric exchanges likely depends on the thickness of the ice. Specifically, the study indicates a predominant influence of brine volume expansion/contraction, brine dissolution/concentration and calcium carbonate formation/dissolution at sites characterized by a thick sea-ice cover, such that surface warming leads to an uptake of CO 2 and vice versa, while convective overturning within the sea-ice brines dominate at sites characterized by comparatively thin sea-ice cover, such that nighttime surface cooling leads to an uptake of CO 2 to the extent permitted by simultaneous formation of superimposed ice in the lower snow column.

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“…2004; Nomura et al, 2006;Papadimitriou et al, 2004;Rysgaard et al, 2007Rysgaard et al, , 2011Rysgaard et al, , 2012Rysgaard et al, , 2013.…”

Section: Introductionunclassified

Winter observations of CO2 exchange between sea ice and the atmosphere in a coastal fjord environment

et al. 2015

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“…4.2) and ikaite concentrations increase with increasing bulk salinity and TA and DIC concentrations. If ikaite crystals remain trapped in the sea ice but the CO 2 produced by ikaite precipitation is removed from the sea ice, either by gravity drainage (e.g., Rysgaard et al, 2007) or by being released to the atmosphere (e.g., Geilfus et al, 2013a), then the dissolution of ikaite during sea ice melt will result in the release of excess TA that is stored in ikaite, increasing the buffering capacity of sea ice and surface meltwater and 365 enhancing CO 2 uptake by the ocean (i.e., the sea ice driven carbon pump; Rysgaard et al, 2007;2009;2011). In the mid-1980s, multi-year sea ice accounted for 70% of Arctic winter sea ice extent but this dropped to less than 20% by 2012 (Stroeve et al, 2014).…”

Section: Influence Of Ikaite In Ice Covered Seasmentioning

confidence: 99%

“…and Arctic sea ice (Dieckmann et al, 2008;2010) and may play a significant role in the sea ice carbon pump (Rysgaard et al, 2011;Parmentier et al, 2013), but the spatial and temporal dynamics of ikaite in sea ice are poorly understood (Rysgaard et al, 2014). Ikaite that remains trapped in the sea ice matrix during the ice growth season will store TA in the sea ice, which increases the buffering capacity of sea ice and meltwater and becoming a source of excess TA to seawater when ikaite dissolves during sea ice melt, enhancing CO 2 uptake by the ocean (RysgaardSuite version 4.0.0 software.…”

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confidence: 99%

Quantification of calcium carbonate (ikaite) in first– and multi–year sea ice

Kyle

Rysgaard

Wang

et al. 2017

Preprint

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Ikaite (CaCO 3 •6H 2 O) is a metastable calcium carbonate mineral that forms at low temperature and/or high pressure. 20Ikaite precipitates in sea ice and may play a significant role in air-sea CO 2 exchange in ice covered seas and oceans.However, the spatial and temporal dynamics of ikaite in sea ice are poorly understood due to few available measurements and time consuming analytical techniques. Here, we present a new method for quantifying ikaite in sea ice and compare it with a more time-consuming imaging technique currently in use. In short, sea ice cores were melted at low temperatures (<4°C), filtered for ikaite crystals that subsequently were dissolved and analyzed as 25 dissolved inorganic carbon (DIC). The new method was applied on cores from experimental sea ice in Winnipeg ice algae were present. The higher abundance of ikaite in young first-year sea ice indicates that its concentrations will likely increase in the Arctic as a result of the recent rapid decline of the multi-year ice cover and increasing presence of seasonal sea ice. As a result, it is likely that ikaite will play a more significant role in air-sea CO 2 exchange in ice-covered seas in the future.

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“…Other processes affect the pCO 2 concentrations within sea ice such as the precipitation and dissolution of calcium carbonate Geilfus et al, 2012bGeilfus et al, , 2013aPapadimitriou et al 2007Papadimitriou et al , 2012Rysgaard et al, 2007Rysgaard et al, , 2011Rysgaard et al, , 2013. During the sea-ice melt, the carbonate dissolution promotes lower pCO 2 conditions (Rysgaard et al, 2011).…”

Section: Pcomentioning

confidence: 99%

CO2 and CH4 in sea ice from a subarctic fjord under influence of riverine input

et al. 2014

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Abstract. We present the CH 4 concentration [CH 4 ], the partial pressure of CO 2 (pCO 2 ) and the total gas content in bulk sea ice from subarctic, land-fast sea ice in the Kapisillit fjord, Greenland. Fjord systems are characterized by freshwater runoff and riverine input and based on δ 18 O data, we show that > 30 % of the surface water originated from periodic river input during ice growth. This resulted in fresher sea-ice layers with higher gas content than is typical from marine sea ice. The bulk ice [CH 4 ] ranged from 1.8 to 12.1 nmol L −1 , which corresponds to a partial pressure ranging from 3 to 28 ppmv. This is markedly higher than the average atmospheric methane content of 1.9 ppmv. Evidently most of the trapped methane within the ice was contained inside bubbles, and only a minor portion was dissolved in the brines. The bulk ice pCO 2 ranged from 60 to 330 ppmv indicating that sea ice at temperatures above −4 • C is undersaturated compared to the atmosphere (390 ppmv). This study adds to the few existing studies of CH 4 and CO 2 in sea ice, and we conclude that subarctic seawater can be a sink for atmospheric CO 2 , while being a net source of CH 4 .

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Sea ice contribution to the air–sea CO<sub>2</sub> exchange in the Arctic and Southern Oceans

Cited by 88 publications

References 28 publications

Winter observations of CO<sub>2</sub> exchange between sea ice and the atmosphere in a coastal fjord environment

Winter observations of CO<sub>2</sub> exchange between sea ice and the atmosphere in a coastal fjord environment

Quantification of calcium carbonate (ikaite) in first– and multi–year sea ice

CO<sub>2</sub> and CH<sub>4</sub> in sea ice from a subarctic fjord under influence of riverine input

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Sea ice contribution to the air–sea CO<sub>2</sub> exchange in the Arctic and Southern Oceans

Cited by 88 publications

References 28 publications

Winter observations of CO&lt;sub&gt;2&lt;/sub&gt; exchange between sea ice and the atmosphere in a coastal fjord environment

Winter observations of CO&lt;sub&gt;2&lt;/sub&gt; exchange between sea ice and the atmosphere in a coastal fjord environment

Quantification of calcium carbonate (ikaite) in first– and multi–year sea ice

CO&lt;sub&gt;2&lt;/sub&gt; and CH&lt;sub&gt;4&lt;/sub&gt; in sea ice from a subarctic fjord under influence of riverine input

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Winter observations of CO<sub>2</sub> exchange between sea ice and the atmosphere in a coastal fjord environment

Winter observations of CO<sub>2</sub> exchange between sea ice and the atmosphere in a coastal fjord environment

CO<sub>2</sub> and CH<sub>4</sub> in sea ice from a subarctic fjord under influence of riverine input