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(Table 6) Chlorophyll a uptake, nitrate uptake and export, and primary production rates in the Amundsen Sea (2012)

Alderkamp, Anne-Carlijn ; Mills, Matthew M ; van Dijken, Gert L ; [et al.]

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Publication Date: 2023-12-12

Keywords: Amundsen Sea; Area/locality; Chlorophyll a, areal concentration; Chlorophyll a, standard deviation; DynaLiFe; Nathaniel B. Palmer; NBP0901; NBP0901_var; Nitrate, integrated; Nitrate, standard deviation; Primary production of carbon, standard deviation; Primary production of carbon per area, daily; Sample amount; Water sample; WS

Type: Dataset

Format: text/tab-separated-values, 63 data points

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(Table 1) Nutrient concentrations and carbon isotopes of sea ice segments and brine sampled during Nathaniel B. Palmer cruises NBP98-07 and NBP06-08, Ross Sea (2010)

Munro, David R ; Dunbar, Robert B ; Mucciarone, David A ; [et al.]

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In: Supplement to: Munro, David R; Dunbar, Robert B; Mucciarone, David A; Arrigo, Kevin R; Long, Matthew C (2010): Stable isotope composition of dissolved inorganic carbon and particulate organic carbon in sea ice from the Ross Sea, Antarctica. Journal of Geophysical Research, 115(C9), C09005, https://doi.org/10.1029/2009JC005661

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Publication Date: 2024-05-22

Description: We examined controls on the carbon isotopic composition of sea ice brines and organic matter during cruises to the Ross Sea, Antarctica in November/December 1998 and November/December 2006. Brine samples were analyzed for salinity, nutrients, total dissolved inorganic carbon (sum CO2), and the 13C/12C ratio of Sum CO2 (d13C(sum CO2)). Particulate organic matter from sea ice cores was analyzed for percent particulate organic carbon (POC), percent total particulate nitrogen (TPN), and stable carbon isotopic composition (d13C(POC)). Sum CO2 in sea ice brines ranged from 1368 to 7149 µmol/kg, equivalent to 1483 to 2519 µmol/kg when normalized to 34.5 psu salinity (s sum CO2), the average salinity of Ross Sea surface waters. Sea ice primary producers removed up to 34% of the available sum CO2, an amount much higher than the maximum removal observed in sea ice free water. Carbonate precipitation and CO2 degassing may reduce s sum CO2 by a similar amount (e.g., 30%) in the most hypersaline sea ice environments, although brine volumes are low in very cold ice that supports these brines. Brine d13C(sum CO2) ranged from -2.6 to +8.0 per mil while d13C(POC) ranged from -30.5 to -9.2 per mil. Isotopic enrichment of the sum CO2 pool via net community production accounts for some but not all carbon isotopic enrichment of sea ice POC. Comparisons of s sum CO2, d13C(sum CO2), and d13C(POC) within sea ice suggest that epsilon p (the net photosynthetic fractionation factor) for sea ice algae is ~8 per mil smaller than the epsilon p observed for phytoplankton in open water regions of the Ross Sea. These results have implications for modeling of carbon uptake and transformation in the ice-covered ocean and for reconstruction of past sea ice extent based on stable isotopic composition of organic matter in sediment cores.

Keywords: Ammonium; Ammonium, standard deviation; Auto-analyzer II, Technicon; Carbon, organic, particulate; Carbon, organic, particulate, integrated; Carbon, organic, particulate, standard deviation; Carbon dioxide; Carbon dioxide, standard deviation; CORSACS II; DATE/TIME; Date/time end; Event label; International Polar Year (2007-2008); IPY; Mass spectrometer Finnigan MAT 252; Nathaniel B. Palmer; NBP0608; NBP0608_all; NBP9807; NBP9807_all; NBP9807_early; NBP9807_late; Nitrate; Nitrate, standard deviation; Nitrite; Nitrite, standard deviation; Nitrogen, inorganic; Nitrogen, inorganic, standard deviation; Nitrogen, particulate; Nitrogen, particulate, standard deviation; Phosphate; Phosphate, standard deviation; ROAVERRS; Ross Sea; Salinity, brine; Salinity, standard deviation; Sample amount, subset; Sample type; Silicate; Silicate, standard deviation; SNOW; Snow/ice sample; δ13C, carbon dioxide, atmospheric; δ13C, carbon dioxide, standard deviation; δ13C, particulate organic carbon; δ13C, standard deviation

Type: Dataset

Format: text/tab-separated-values, 404 data points

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The influence of winter water on phytoplankton blooms in the Chukchi Sea (2015)

Lowry, Kate E. ; Pickart, Robert S. ; Mills, Matthew M. ; [et al.]

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Publication Date: 2022-05-25

Description: Author Posting. © The Author(s), 2015. This is the author's version of the work. It is posted here by permission of Elsevier for personal use, not for redistribution. The definitive version was published in Deep Sea Research Part II: Topical Studies in Oceanography 118 (2015): 53-72, doi:10.1016/j.dsr2.2015.06.006.

Description: The flow of nutrient-rich winter water (WW) through the Chukchi Sea plays an important and previously uncharacterized role in sustaining summer phytoplankton blooms. Using hydrographic and biogeochemical data collected as part of the ICESCAPE program (June-July 2010-11), we examined phytoplankton bloom dynamics in relation to the distribution and circulation of WW (defined as water with potential temperature ≤ -1.6°C) across the Chukchi shelf. Characterized by high concentrations of nitrate (mean: 12.3 ± 5.13 μmol L-1) that typically limits primary production in this region, WW was correlated with extremely high phytoplankton biomass, with mean chlorophyll a concentrations that were three-fold higher in WW (8.64 ± 9.75 μg L-1) than in adjacent warmer water (2.79 ± 5.58 μg L-1). Maximum chlorophyll a concentrations (~30 μg L-1) were typically positioned at the interface between nutrient-rich WW and shallower, warmer water with more light availability. Comparing satellite-based calculations of open water duration to phytoplankton biomass, nutrient concentrations, and oxygen saturation revealed widespread evidence of under-ice blooms prior to our sampling, with biogeochemical properties indicating that blooms had already terminated in many places where WW was no longer present. Our results suggest that summer phytoplankton blooms are sustained for a longer duration along the pathways of nutrient-rich WW and that biological hotspots in this region (e.g. the mouth of Barrow Canyon) are largely driven by the flow and confluence of these extremely productive pathways of WW that flow across the Chukchi shelf.

Description: This material is based upon work supported by the National Aeronautic and Space Administration (NASA) under Grant No. NNX10AF42G and the National Science Foundation Graduate Research Fellowship under Grant No. DGE-0645962 to K.E. Lowry.

Keywords: Phytoplankton ; Winter water ; Under-ice blooms ; Biological hotspots ; Chukchi Sea

Repository Name: Woods Hole Open Access Server

Type: Preprint

Format: application/pdf

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Under-ice phytoplankton blooms inhibited by spring convective mixing in refreezing leads (2018)

Lowry, Kate E. ; Pickart, Robert S. ; Selz, Virginia ; [et al.]

John Wiley & Sons

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Publication Date: 2022-05-26

Description: Author Posting. © American Geophysical Union, 2018. This article is posted here by permission of American Geophysical Union for personal use, not for redistribution. The definitive version was published in Journal of Geophysical Research: Oceans 123 (2018): 90–109, doi:10.1002/2016JC012575.

Description: Spring phytoplankton growth in polar marine ecosystems is limited by light availability beneath ice-covered waters, particularly early in the season prior to snowmelt and melt pond formation. Leads of open water increase light transmission to the ice-covered ocean and are sites of air-sea exchange. We explore the role of leads in controlling phytoplankton bloom dynamics within the sea ice zone of the Arctic Ocean. Data are presented from spring measurements in the Chukchi Sea during the Study of Under-ice Blooms In the Chukchi Ecosystem (SUBICE) program in May and June 2014. We observed that fully consolidated sea ice supported modest under-ice blooms, while waters beneath sea ice with leads had significantly lower phytoplankton biomass, despite high nutrient availability. Through an analysis of hydrographic and biological properties, we attribute this counterintuitive finding to springtime convective mixing in refreezing leads of open water. Our results demonstrate that waters beneath loosely consolidated sea ice (84–95% ice concentration) had weak stratification and were frequently mixed below the critical depth (the depth at which depth-integrated production balances depth-integrated respiration). These findings are supported by theoretical model calculations of under-ice light, primary production, and critical depth at varied lead fractions. The model demonstrates that under-ice blooms can form even beneath snow-covered sea ice in the absence of mixing but not in more deeply mixed waters beneath sea ice with refreezing leads. Future estimates of primary production should account for these phytoplankton dynamics in ice-covered waters.

Description: National Science Foundation (NSF) Grant Numbers: PLR-1304563 , PLR-1303617; KEL; NSF Graduate Research Fellowship Program Grant Number: DGE-0645962

Description: 2018-07-07

Keywords: Phytoplankton ; Under-ice blooms ; Leads ; Convective mixing ; Arctic ; Sea ice

Repository Name: Woods Hole Open Access Server

Type: Article

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