Characterization of the Water Masses in the Shelf Region of the Bering and Chukchi Seas With Fluorescent Organic Matter

Yamashita, Youhei; Yagi, Yuki; Ueno, Hiromichi; Ooki, Atsushi; Hirawake, Toru

doi:10.1029/2019jc015476

Cited by 18 publications

(12 citation statements)

References 58 publications

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“…Biogeographically, the classification of tintinnid genera (Neritic, species largely restricted to nearshore waters; Boreal, species restricted to Arctic and Subarctic waters; Cosmopolitan, species distributed widely in the world ocean) was based on Pierce and Turner (1993) and Dolan and Pierce (2013) . The threshold for Pacific Inflow Water was 4 ° C as Yamashita et al (2019) in our results. Data of total surface heat flux (SHF = net solar radiation + net longwave radiation + sensible heat flux + latent heat flux) were obtained from the European Centre for Medium-Range Weather Forecasts (ECMWF).…”

Section: Methodssupporting

confidence: 69%

Hydrographic Feature Variation Caused Pronounced Differences in Planktonic Ciliate Community in the Pacific Arctic Region in the Summer of 2016 and 2019

Wang

Yang

et al. 2022

Front. Microbiol.

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Planktonic ciliates are an important component of microzooplankton, but there is limited understanding of their responses to changing environmental conditions in the Pacific Arctic Region. We investigated the variations of ciliate community structure and their relationships with environmental features in the Pacific Arctic Region in the summer of 2016 and 2019. The Pacific water was warmer and more saline in 2019 than in 2016. The abundance and biomass of total ciliate and aloricate ciliate were significantly higher in 2019 than those in 2016, while those of tintinnid were significantly lower. The dominant aloricate ciliate changed from large size-fraction (> 30 μm) in 2016 to small size-fraction (10–20 μm) in 2019. More tintinnid species belonging to cosmopolitan genera were found in 2019 than in 2016, and the distribution of tintinnid species (Codonellopsis frigida, Ptychocylis obtusa, and Salpingella sp.1) in 2019 expanded by 5.9, 5.2, and 8.8 degrees further north of where they occurred in 2016. The environmental variables that best-matched tintinnid distributions were temperature and salinity, while the best match for aloricate ciliate distributions was temperature. Therefore, the temperature might play a key role in ciliate distribution. These results provide basic data on the response of the planktonic ciliate community to hydrographic variations and implicate the potential response of microzooplankton to Pacification as rapid warming progresses in the Pacific Arctic Region.

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Section: Methodssupporting

confidence: 69%

Hydrographic Feature Variation Caused Pronounced Differences in Planktonic Ciliate Community in the Pacific Arctic Region in the Summer of 2016 and 2019

Wang

Yang

et al. 2022

Front. Microbiol.

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“…Optical properties including absorbing and fluorescing properties have been used to assess DOM composition and fate (Coble, 2007; Nelson & Gauglitz, 2016), and trace water masses in Arctic waters (Dainard and Guéguen, 2013; Gonçalves‐Araujo et al., 2016; Guéguen et al., 2014; Logvinova et al., 2015; Stedmon et al., 2011; Walker et al., 2009; Yamashita et al., 2019). Colored DOM (CDOM) is defined as the fraction of DOM (up to 25%; Benner, 2002) that has light absorbing properties in the ultraviolet (UV) and visible regions of the electromagnetic spectrum (Hansell & Carlson, 2002) whereas the fluorescent DOM (FDOM) refers to the DOM pool that fluoresces.…”

Section: Introductionmentioning

confidence: 99%

“…and Gonçalves-Araujo et al, 2016;Guéguen et al, 2014;Logvinova et al, 2015;Stedmon et al, 2011;Walker et al, 2009;Yamashita et al, 2019). Colored DOM (CDOM) is defined as the fraction of DOM (up to 25%; Benner, 2002) that has light absorbing properties in the ultraviolet (UV) and visible regions of the electromagnetic spectrum (Hansell & Carlson, 2002) whereas the fluorescent DOM (FDOM) refers to the DOM pool that fluoresces.…”

mentioning

confidence: 99%

Long‐term Trends in Dissolved Organic Matter Composition and Its Relation to Sea Ice in the Canada Basin, Arctic Ocean (2007–2017)

DeFrancesco

Guéguen

2021

JGR Oceans

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The Arctic region is undeniably changing, with significant losses in sea ice cover and changing riverine inputs to the Arctic Ocean (Peterson et al., 2006). A record low sea ice extent was reported in September 2012 (D. Perovich et al., 2012) and the summer sea ice has not exceeded or returned to pre-2007 levels yet (Perovich et al., 2019). The rapid reduction of Arctic summer sea ice causes an increase in the amount of light penetrating into the ocean (Nicolaus et al., 2012), enhancing sea-ice melt (Markus et al., 2009) and affecting the aquatic ecosystems (Arrigo & van Dijken, 2015; Arrigo et al., 2012). Arrigo and van Dijken (2015) showed that the 30% increase in the annual net primary production in the Arctic Ocean between 1998 and 2012 was associated with reduced sea ice. Planktonic dissolved organic matter (DOM) is considered as a major source of marine DOM (Osburn et al., 2019). The increase in the primary production of the Arctic Ocean (Arrigo et al., 2008) could contribute to increased production of autochthonous DOM in polar waters (Shen et al., 2018). Optical properties including absorbing and fluorescing properties have been used to assess DOM composition and fate (Coble, 2007; Nelson & Gauglitz, 2016), and trace water masses in Arctic waters (Dainard Abstract Absorbance and fluorescence properties of dissolved organic matter (DOM) were measured in the upper and lower polar mixed layer (UPML and LPML, respectively) over an 11-year period (2007-2017) to assess for yearly changes in the quality and quantity of colored and fluorescent DOM (CDOM and FDOM, respectively) in relation with sea ice concentration in central Canada Basin waters. The LPML waters were enriched in CDOM, total dissolved lignin phenols, terrestrial humic-like C1, and in microbial humic-like C2 and C7 relative to the UPML waters (p > 0.05). The low ice years (i.e., 2012, 2016-2017) were characterized by lower humic-like fluorescence intensity (C4 only) and abundances relative to high ice years (i.e., 2007-2011, 2013-2015), likely the result of the preferential photoalteration of humic material when sea ice concentration was reduced. Significant time increases were found in tryptophan-like C3 in UPML and terrestrially derived humic-like C4 in LPML, suggesting an increase in the proteinaceous and terrigenous character of FDOM in UPML and LPML during the 11-year period, respectively. No interannual variation in dissolved organic carbon concentration was found in LPML and UPML. Weak but positive Spearman correlations were found between the humic-like intensities and abundances, and sea ice concentration in UPML waters, a consequence of reduced photodegradation in ice covered waters. This 11-year survey provides the first insight into the influence of summer sea ice concentration and river runoff on the quality and quantity of CDOM and FDOM. Plain Language Summary The Arctic Ocean is a hostile environment undergoing rapid changes. However, it is not clear how the fast decline in sea cover and the increase in freshwater content in the Beauf...

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“…Until recently, various trends in the properties of these water masses have been reported in the Chukchi Sea (Ershova et al, 2015b;Corlett and Pickart, 2017;Danielson et al, 2017;Pickart et al, 2019). In particular, excellent analyses of water masses in this area have been performed by Pickart and colleagues (Pickart and Stossmeister, 2008;Pickart et al, 2010Pickart et al, , 2016Pickart et al, , 2019Brugler et al, 2014;Pickart, 2015, 2016;Pisareva et al, 2015;Corlett and Pickart, 2017;Linders et al, 2017;Lin et al, 2019); many previous studies have cited or applied Pickart's classifications when identifying water masses (e.g., Ershova et al, 2015a;Weingartner et al, 2017;Yamashita et al, 2019). Due to the purpose and region of this study, the water masses were identified with reference to the recent and well-organized methods of classification in Corlett and Pickart (2017) and Pickart et al (2019).…”

Section: Water Mass Identificationmentioning

confidence: 99%

Mass Occurrence of Pacific Copepods in the Southern Chukchi Sea During Summer: Implications of the High-Temperature Bering Summer Water

Kim

Cho

et al. 2020

Front. Mar. Sci.

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The Bering Strait is the only gateway to the Chukchi Sea from the Pacific Ocean and is a major route of Pacific water inflow. We recently investigated the occurrence of Pacific copepod species along with the warming of the Chukchi Sea and sought to identify the cause of the mass occurrence these copepods through an analysis of the water masses flowing through the Bering Strait. Zooplankton and Conductivity-Temperature-Depth (CTD) data collection was conducted in the Chukchi Sea and Bering Strait from 2014 to 2016. In addition, mooring systems installed in the Bering Strait were analyzed to obtain water temperature and salinity data during summer to understand the properties of the water masses. In 2015, a high abundance of Pacific copepod species (Eucalanus bungii, Metridia pacifica, and Neocalanus spp.) was observed in Bering Summer Water (BSW), which was relatively warm compared to measurements obtained from 2014 to 2016. As further confirmation, our results were consistent with 2007, 2009, and 2012 data, which showed that the abundance of Pacific copepod species was proportional to the temperature of the BSW entering the Chukchi Sea. In conclusion, we reconfirmed that Pacific copepod species are entering the Chukchi Sea along with BSW, and we newly discovered that their high abundance coincided with the relatively warm BSW, instead of other water masses. These findings suggest that the inflow of the high-temperature BSW (>3 • C) plays an important role in the mass occurrence of Pacific copepod species in the southern Chukchi Sea.

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Characterization of the Water Masses in the Shelf Region of the Bering and Chukchi Seas With Fluorescent Organic Matter

Cited by 18 publications

References 58 publications

Hydrographic Feature Variation Caused Pronounced Differences in Planktonic Ciliate Community in the Pacific Arctic Region in the Summer of 2016 and 2019

Hydrographic Feature Variation Caused Pronounced Differences in Planktonic Ciliate Community in the Pacific Arctic Region in the Summer of 2016 and 2019

Long‐term Trends in Dissolved Organic Matter Composition and Its Relation to Sea Ice in the Canada Basin, Arctic Ocean (2007–2017)

Mass Occurrence of Pacific Copepods in the Southern Chukchi Sea During Summer: Implications of the High-Temperature Bering Summer Water

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