Articles | Volume 7, issue 5
https://doi.org/10.5194/bg-7-1769-2010
© Author(s) 2010. This work is distributed under
the Creative Commons Attribution 3.0 License.
the Creative Commons Attribution 3.0 License.
https://doi.org/10.5194/bg-7-1769-2010
© Author(s) 2010. This work is distributed under
the Creative Commons Attribution 3.0 License.
the Creative Commons Attribution 3.0 License.
28 May 2010
Seasonal distribution of dissolved inorganic carbon and net community production on the Bering Sea shelf
J. T. Mathis
University of Alaska Fairbanks, School of Fisheries and Ocean Sciences, 245 O'Neill BLDG, Fairbanks, AK 99775 USA
J. N. Cross
University of Alaska Fairbanks, School of Fisheries and Ocean Sciences, 245 O'Neill BLDG, Fairbanks, AK 99775 USA
N. R. Bates
Bermuda Institute of Ocean Sciences, 17 Biological Lane, Ferry Reach, GE01, Bermuda
S. Bradley Moran
University of Rhode Island, 70 Lower College Rd., Kingston, RI 02881, USA
M. W. Lomas
Bermuda Institute of Ocean Sciences, 17 Biological Lane, Ferry Reach, GE01, Bermuda
C. W. Mordy
National Oceanic and Atmospheric Administration, Pacific Marine Environmental Lab, 7600 Sand Point Way NE, Seattle, WA 98115, USA
P. J. Stabeno
National Oceanic and Atmospheric Administration, Pacific Marine Environmental Lab, 7600 Sand Point Way NE, Seattle, WA 98115, USA
Related subject area
Biogeochemistry: Coastal Ocean
Temporal and spatial evolution of bottom-water hypoxia in the St Lawrence estuarine system
Significant nutrient consumption in the dark subsurface layer during a diatom bloom: a case study on Funka Bay, Hokkaido, Japan
Contrasts in dissolved, particulate, and sedimentary organic carbon from the Kolyma River to the East Siberian Shelf
Sediment quality assessment in an industrialized Greek coastal marine area (western Saronikos Gulf)
Limits and CO2 equilibration of near-coast alkalinity enhancement
Role of phosphorus in the seasonal deoxygenation of the East China Sea shelf
Interannual variability of the initiation of the phytoplankton growing period in two French coastal ecosystems
Spatio-temporal distribution, photoreactivity and environmental control of dissolved organic matter in the sea-surface microlayer of the eastern marginal seas of China
Metabolic alkalinity release from large port facilities (Hamburg, Germany) and impact on coastal carbon storage
A Numerical reassessment of the Gulf of Mexico carbon system in connection with the Mississippi River and global ocean
Observed and projected global warming pressure on coastal hypoxia
Benthic alkalinity fluxes from coastal sediments of the Baltic and North seas: comparing approaches and identifying knowledge gaps
Investigating the effect of nickel concentration on phytoplankton growth to assess potential side-effects of ocean alkalinity enhancement
Unprecedented summer hypoxia in southern Cape Cod Bay: an ecological response to regional climate change?
Interannual variabilities, long-term trends, and regulating factors of low-oxygen conditions in the coastal waters off Hong Kong
Zooplankton community succession and trophic links during a mesocosm experiment in the coastal upwelling off Callao Bay (Peru)
Production and accumulation of reef framework by calcifying corals and macroalgae on a remote Indian Ocean Cay
Causes of the extensive hypoxia in the Gulf of Riga in 2018
Trawling effects on biogeochemical processes are mediated by fauna in high-energy biogenic-reef-inhabited coastal sediments
Drought recorded by Ba∕Ca in coastal benthic foraminifera
A nitrate budget of the Bohai Sea based on an isotope mass balance model
Suspended particulate matter drives the spatial segregation of nitrogen turnover along the hyper-turbid Ems estuary
Marine CO2 system variability along the northeast Pacific Inside Passage determined from an Alaskan ferry
Reviews and syntheses: Spatial and temporal patterns in seagrass metabolic fluxes
Mixed layer depth dominates over upwelling in regulating the seasonality of ecosystem functioning in the Peruvian upwelling system
Temporal dynamics of surface ocean carbonate chemistry in response to natural and simulated upwelling events during the 2017 coastal El Niño near Callao, Peru
Pelagic primary production in the coastal Mediterranean Sea: variability, trends, and contribution to basin-scale budgets
Contrasting patterns of carbon cycling and dissolved organic matter processing in two phytoplankton–bacteria communities
Biophysical controls on seasonal changes in the structure, growth, and grazing of the size-fractionated phytoplankton community in the northern South China Sea
Seasonal dispersal of fjord meltwaters as an important source of iron and manganese to coastal Antarctic phytoplankton
Modeling cyanobacteria life cycle dynamics and historical nitrogen fixation in the Baltic Proper
Simultaneous assessment of oxygen- and nitrate-based net community production in a temperate shelf sea from a single ocean glider
Reviews and syntheses: Physical and biogeochemical processes associated with upwelling in the Indian Ocean
Particulate organic carbon dynamics in the Gulf of Lion shelf (NW Mediterranean) using a coupled hydrodynamic–biogeochemical model
Technical note: Novel triple O2 sensor aquatic eddy covariance instrument with improved time shift correction reveals central role of microphytobenthos for carbon cycling in coral reef sands
Long-term spatiotemporal variations in and expansion of low-oxygen conditions in the Pearl River estuary: a study synthesizing observations during 1976–2017
Fe-binding organic ligands in coastal and frontal regions of the western Antarctic Peninsula
Temporal variability and driving factors of the carbonate system in the Aransas Ship Channel, TX, USA: a time series study
Nitrogen loss processes in response to upwelling in a Peruvian coastal setting dominated by denitrification – a mesocosm approach
Retracing hypoxia in Eckernförde Bight (Baltic Sea)
The impact of the freeze–melt cycle of land-fast ice on the distribution of dissolved organic matter in the Laptev and East Siberian seas (Siberian Arctic)
The fate of upwelled nitrate off Peru shaped by submesoscale filaments and fronts
Coastal processes modify projections of some climate-driven stressors in the California Current System
Upwelling-induced trace gas dynamics in the Baltic Sea inferred from 8 years of autonomous measurements on a ship of opportunity
Destruction and reinstatement of coastal hypoxia in the South China Sea off the Pearl River estuary
Hypersaline tidal flats as important “blue carbon” systems: a case study from three ecosystems
Drivers and impact of the seasonal variability of the organic carbon offshore transport in the Canary upwelling system
Organic carbon densities and accumulation rates in surface sediments of the North Sea and Skagerrak
An observation-based evaluation and ranking of historical Earth system model simulations in the northwest North Atlantic Ocean
Characterizing the origins of dissolved organic carbon in coastal seawater using stable carbon isotope and light absorption characteristics
Mathilde Jutras, Alfonso Mucci, Gwenaëlle Chaillou, William A. Nesbitt, and Douglas W. R. Wallace
Biogeosciences, 20, 839–849, https://doi.org/10.5194/bg-20-839-2023, https://doi.org/10.5194/bg-20-839-2023, 2023
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The deep waters of the lower St Lawrence Estuary and gulf have, in the last decades, experienced a strong decline in their oxygen concentration. Below 65 µmol L-1, the waters are said to be hypoxic, with dire consequences for marine life. We show that the extent of the hypoxic zone shows a seven-fold increase in the last 20 years, reaching 9400 km2 in 2021. After a stable period at ~ 65 µmol L⁻¹ from 1984 to 2019, the oxygen level also suddenly decreased to ~ 35 µmol L-1 in 2020.
Sachi Umezawa, Manami Tozawa, Yuichi Nosaka, Daiki Nomura, Hiroji Onishi, Hiroto Abe, Tetsuya Takatsu, and Atsushi Ooki
Biogeosciences, 20, 421–438, https://doi.org/10.5194/bg-20-421-2023, https://doi.org/10.5194/bg-20-421-2023, 2023
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We conducted repetitive observations in Funka Bay, Japan, during the spring bloom 2019. We found nutrient concentration decreases in the dark subsurface layer during the bloom. Incubation experiments confirmed that diatoms could consume nutrients at a substantial rate, even in darkness. We concluded that the nutrient reduction was mainly caused by nutrient consumption by diatoms in the dark.
Dirk Jong, Lisa Bröder, Tommaso Tesi, Kirsi H. Keskitalo, Nikita Zimov, Anna Davydova, Philip Pika, Negar Haghipour, Timothy I. Eglinton, and Jorien E. Vonk
Biogeosciences, 20, 271–294, https://doi.org/10.5194/bg-20-271-2023, https://doi.org/10.5194/bg-20-271-2023, 2023
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With this study, we want to highlight the importance of studying both land and ocean together, and water and sediment together, as these systems function as a continuum, and determine how organic carbon derived from permafrost is broken down and its effect on global warming. Although on the one hand it appears that organic carbon is removed from sediments along the pathway of transport from river to ocean, it also appears to remain relatively ‘fresh’, despite this removal and its very old age.
Georgia Filippi, Manos Dassenakis, Vasiliki Paraskevopoulou, and Konstantinos Lazogiannis
Biogeosciences, 20, 163–189, https://doi.org/10.5194/bg-20-163-2023, https://doi.org/10.5194/bg-20-163-2023, 2023
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The pollution of the western Saronikos Gulf from heavy metals has been examined through the study of marine sediment cores. It is a deep gulf (maximum depth 440 m) near Athens affected by industrial and volcanic activity. Eight cores were received from various stations and depths and analysed for their heavy metal content and geochemical characteristics. The results were evaluated by using statistical methods, environmental indicators and comparisons with old data.
Jing He and Michael D. Tyka
Biogeosciences, 20, 27–43, https://doi.org/10.5194/bg-20-27-2023, https://doi.org/10.5194/bg-20-27-2023, 2023
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Recently, ocean alkalinity enhancement (OAE) has gained interest as a scalable way to address the urgent need for negative CO2 emissions. In this paper we examine the capacity of different coastlines to tolerate alkalinity enhancement and the time scale of CO2 uptake following the addition of a given quantity of alkalinity. The results suggest that OAE has significant potential and identify specific favorable and unfavorable coastlines for its deployment.
Arnaud Laurent, Haiyan Zhang, and Katja Fennel
Biogeosciences, 19, 5893–5910, https://doi.org/10.5194/bg-19-5893-2022, https://doi.org/10.5194/bg-19-5893-2022, 2022
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The Changjiang is the main terrestrial source of nutrients to the East China Sea (ECS). Nutrient delivery to the ECS has been increasing since the 1960s, resulting in low oxygen (hypoxia) during phytoplankton decomposition in summer. River phosphorus (P) has increased less than nitrogen, and therefore, despite the large nutrient delivery, phytoplankton growth can be limited by the lack of P. Here, we investigate this link between P limitation, phytoplankton production/decomposition, and hypoxia.
Coline Poppeschi, Guillaume Charria, Anne Daniel, Romaric Verney, Peggy Rimmelin-Maury, Michaël Retho, Eric Goberville, Emilie Grossteffan, and Martin Plus
Biogeosciences, 19, 5667–5687, https://doi.org/10.5194/bg-19-5667-2022, https://doi.org/10.5194/bg-19-5667-2022, 2022
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This paper aims to understand interannual changes in the initiation of the phytoplankton growing period (IPGP) in the current context of global climate changes over the last 20 years. An important variability in the timing of the IPGP is observed with a trend towards a later IPGP during this last decade. The role and the impact of extreme events (cold spells, floods, and wind burst) on the IPGP is also detailed.
Lin Yang, Jing Zhang, Anja Engel, and Gui-Peng Yang
Biogeosciences, 19, 5251–5268, https://doi.org/10.5194/bg-19-5251-2022, https://doi.org/10.5194/bg-19-5251-2022, 2022
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Enrichment factors of dissolved organic matter (DOM) in the eastern marginal seas of China exhibited a significant spatio-temporal variation. Photochemical and enrichment processes co-regulated DOM enrichment in the sea-surface microlayer (SML). Autochthonous DOM was more frequently enriched in the SML than terrestrial DOM. DOM in the sub-surface water exhibited higher aromaticity than that in the SML.
Mona Norbisrath, Johannes Pätsch, Kirstin Dähnke, Tina Sanders, Gesa Schulz, Justus E. E. van Beusekom, and Helmuth Thomas
Biogeosciences, 19, 5151–5165, https://doi.org/10.5194/bg-19-5151-2022, https://doi.org/10.5194/bg-19-5151-2022, 2022
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Total alkalinity (TA) regulates the oceanic storage capacity of atmospheric CO2. TA is also metabolically generated in estuaries and influences coastal carbon storage through its inflows. We used water samples and identified the Hamburg port area as the one with highest TA generation. Of the overall riverine TA load, 14 % is generated within the estuary. Using a biogeochemical model, we estimated potential effects on the coastal carbon storage under possible anthropogenic and climate changes.
Le Zhang and Z. George Xue
Biogeosciences, 19, 4589–4618, https://doi.org/10.5194/bg-19-4589-2022, https://doi.org/10.5194/bg-19-4589-2022, 2022
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We adopt a high-resolution carbon model for the Gulf of Mexico (GoM) and calculate the decadal trends of important carbon system variables in the GoM from 2001 to 2019. The GoM surface CO2 values experienced a steady increase over the past 2 decades, and the ocean surface pH is declining. Although carbonate saturation rates remain supersaturated with aragonite, they show a slightly decreasing trend. The northern GoM is a stronger carbon sink than we thought.
Michael M. Whitney
Biogeosciences, 19, 4479–4497, https://doi.org/10.5194/bg-19-4479-2022, https://doi.org/10.5194/bg-19-4479-2022, 2022
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Coastal hypoxia is a major environmental problem of increasing severity. The 21st-century projections analyzed indicate global coastal waters will warm and experience rapid declines in oxygen. The forecasted median coastal trends for increasing sea surface temperature and decreasing oxygen capacity are 48 % and 18 % faster than the rates observed over the last 4 decades. Existing hypoxic areas are expected to worsen, and new hypoxic areas likely will emerge under these warming-related pressures.
Bryce Van Dam, Nele Lehmann, Mary A. Zeller, Andreas Neumann, Daniel Pröfrock, Marko Lipka, Helmuth Thomas, and Michael Ernst Böttcher
Biogeosciences, 19, 3775–3789, https://doi.org/10.5194/bg-19-3775-2022, https://doi.org/10.5194/bg-19-3775-2022, 2022
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We quantified sediment–water exchange at shallow sites in the North and Baltic seas. We found that porewater irrigation rates in the former were approximately twice as high as previously estimated, likely driven by relatively high bioirrigative activity. In contrast, we found small net fluxes of alkalinity, ranging from −35 µmol m−2 h−1 (uptake) to 53 µmol m−2 h−1 (release). We attribute this to low net denitrification, carbonate mineral (re-)precipitation, and sulfide (re-)oxidation.
Jiaying Abby Guo, Robert Strzepek, Anusuya Willis, Aaron Ferderer, and Lennart Thomas Bach
Biogeosciences, 19, 3683–3697, https://doi.org/10.5194/bg-19-3683-2022, https://doi.org/10.5194/bg-19-3683-2022, 2022
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Ocean alkalinity enhancement is a CO2 removal method with significant potential, but it can lead to a perturbation of the ocean with trace metals such as nickel. This study tested the effect of increasing nickel concentrations on phytoplankton growth and photosynthesis. We found that the response to nickel varied across the 11 phytoplankton species tested here, but the majority were rather insensitive. We note, however, that responses may be different under other experimental conditions.
Malcolm E. Scully, W. Rockwell Geyer, David Borkman, Tracy L. Pugh, Amy Costa, and Owen C. Nichols
Biogeosciences, 19, 3523–3536, https://doi.org/10.5194/bg-19-3523-2022, https://doi.org/10.5194/bg-19-3523-2022, 2022
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For two consecutive summers, the bottom waters in southern Cape Cod Bay became severely depleted of dissolved oxygen. Low oxygen levels in bottom waters have never been reported in this area before, and this unprecedented occurrence is likely the result of a new algae species that recently began blooming during the late-summer months. We present data suggesting that blooms of this new species are the result of regional climate change including warmer waters and changes in summer winds.
Zheng Chen, Bin Wang, Chuang Xu, Zhongren Zhang, Shiyu Li, and Jiatang Hu
Biogeosciences, 19, 3469–3490, https://doi.org/10.5194/bg-19-3469-2022, https://doi.org/10.5194/bg-19-3469-2022, 2022
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Deterioration of low-oxygen conditions in the coastal waters off Hong Kong was revealed by monitoring data over two decades. The declining wind forcing and the increasing nutrient input contributed significantly to the areal expansion and intense deterioration of low-oxygen conditions. Also, the exacerbated eutrophication drove a shift in the dominant source of organic matter from terrestrial inputs to in situ primary production, which has probably led to an earlier onset of hypoxia in summer.
Patricia Ayón Dejo, Elda Luz Pinedo Arteaga, Anna Schukat, Jan Taucher, Rainer Kiko, Helena Hauss, Sabrina Dorschner, Wilhelm Hagen, Mariona Segura-Noguera, and Silke Lischka
Biogeosciences Discuss., https://doi.org/10.5194/bg-2022-157, https://doi.org/10.5194/bg-2022-157, 2022
Revised manuscript accepted for BG
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Ocean upwelling regions are highly productive. With ocean warming, severe changes in upwelling frequency and/or intensity and expansion of accompanying oxygen minimum zones are projected. In a field experiment off Peru, we investigated how different upwelling intensities affect the pelagic food web and found failed reproduction of dominant zooplankton. Therefore, changes projected could severely impact reproductive success of zooplankton communities and the pelagic food web in upwelling regions.
M. James McLaughlin, Cindy Bessey, Gary A. Kendrick, John Keesing, and Ylva S. Olsen
EGUsphere, https://doi.org/10.5194/egusphere-2022-467, https://doi.org/10.5194/egusphere-2022-467, 2022
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Coral reefs face increasing pressures from environmental change at present. The coral reef physical framework is formed through the production of calcium carbonate by corals, crustose coralline algae (CCA), and other calcifying algae. The Kimberley bioregion, located in the northern part of Western Australia, has largely escaped land-based anthropogenic impacts and this study provides important data on reef building processes we are lacking from an undisturbed set of marine habitats.
Stella-Theresa Stoicescu, Jaan Laanemets, Taavi Liblik, Māris Skudra, Oliver Samlas, Inga Lips, and Urmas Lips
Biogeosciences, 19, 2903–2920, https://doi.org/10.5194/bg-19-2903-2022, https://doi.org/10.5194/bg-19-2903-2022, 2022
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Coastal basins with high input of nutrients often suffer from oxygen deficiency. In summer 2018, the extent of oxygen depletion was exceptional in the Gulf of Riga. We analyzed observational data and found that extensive oxygen deficiency appeared since the water layer close to the seabed, where oxygen is consumed, was separated from the surface layer. The problem worsens if similar conditions restricting vertical transport of oxygen occur more frequently in the future.
Justin C. Tiano, Jochen Depestele, Gert Van Hoey, João Fernandes, Pieter van Rijswijk, and Karline Soetaert
Biogeosciences, 19, 2583–2598, https://doi.org/10.5194/bg-19-2583-2022, https://doi.org/10.5194/bg-19-2583-2022, 2022
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This study gives an assessment of bottom trawling on physical, chemical, and biological characteristics in a location known for its strong currents and variable habitats. Although trawl gears only removed the top 1 cm of the seabed surface, impacts on reef-building tubeworms significantly decreased carbon and nutrient cycling. Lighter trawls slightly reduced the impact on fauna and nutrients. Tubeworms were strongly linked to biogeochemical and faunal aspects before but not after trawling.
Inda Brinkmann, Christine Barras, Tom Jilbert, Tomas Næraa, K. Mareike Paul, Magali Schweizer, and Helena L. Filipsson
Biogeosciences, 19, 2523–2535, https://doi.org/10.5194/bg-19-2523-2022, https://doi.org/10.5194/bg-19-2523-2022, 2022
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The concentration of the trace metal barium (Ba) in coastal seawater is a function of continental input, such as riverine discharge. Our geochemical records of the severely hot and dry year 2018, and following wet year 2019, reveal that prolonged drought imprints with exceptionally low Ba concentrations in benthic foraminiferal calcium carbonates of coastal sediments. This highlights the potential of benthic Ba / Ca to trace past climate extremes and variability in coastal marine records.
Shichao Tian, Birgit Gaye, Jianhui Tang, Yongming Luo, Wenguo Li, Niko Lahajnar, Kirstin Dähnke, Tina Sanders, Tianqi Xiong, Weidong Zhai, and Kay-Christian Emeis
Biogeosciences, 19, 2397–2415, https://doi.org/10.5194/bg-19-2397-2022, https://doi.org/10.5194/bg-19-2397-2022, 2022
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We constrain the nitrogen budget and in particular the internal sources and sinks of nitrate in the Bohai Sea by using a mass-based and dual stable isotope approach based on δ15N and δ18O of nitrate. Based on available mass fluxes and isotope data an updated nitrogen budget is proposed. Compared to previous estimates, it is more complete and includes the impact of the interior cycle (nitrification) on the nitrate pool. The main external nitrogen sources are rivers contributing 19.2 %–25.6 %.
Gesa Schulz, Tina Sanders, Justus E. E. van Beusekom, Yoana G. Voynova, Andreas Schöl, and Kirstin Dähnke
Biogeosciences, 19, 2007–2024, https://doi.org/10.5194/bg-19-2007-2022, https://doi.org/10.5194/bg-19-2007-2022, 2022
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Estuaries can significantly alter nutrient loads before reaching coastal waters. Our study of the heavily managed Ems estuary (Northern Germany) reveals three zones of nitrogen turnover along the estuary with water-column denitrification in the most upstream hyper-turbid part, nitrate production in the middle reaches and mixing/nitrate uptake in the North Sea. Suspended particulate matter was the overarching control on nitrogen cycling in the hyper-turbid estuary.
Wiley Evans, Geoffrey T. Lebon, Christen D. Harrington, Yuichiro Takeshita, and Allison Bidlack
Biogeosciences, 19, 1277–1301, https://doi.org/10.5194/bg-19-1277-2022, https://doi.org/10.5194/bg-19-1277-2022, 2022
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Information on the marine carbon dioxide system along the northeast Pacific Inside Passage has been limited. To address this gap, we instrumented an Alaskan ferry in order to characterize the marine carbon dioxide system in this region. Data over a 2-year period were used to assess drivers of the observed variability, identify the timing of severe conditions, and assess the extent of contemporary ocean acidification as well as future levels consistent with a 1.5 °C warmer climate.
Melissa Ward, Tye L. Kindinger, Heidi K. Hirsh, Tessa M. Hill, Brittany M. Jellison, Sarah Lummis, Emily B. Rivest, George G. Waldbusser, Brian Gaylord, and Kristy J. Kroeker
Biogeosciences, 19, 689–699, https://doi.org/10.5194/bg-19-689-2022, https://doi.org/10.5194/bg-19-689-2022, 2022
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Here, we synthesize the results from 62 studies reporting in situ rates of seagrass metabolism to highlight spatial and temporal variability in oxygen fluxes and inform efforts to use seagrass to mitigate ocean acidification. Our analyses suggest seagrass meadows are generally autotrophic and variable in space and time, and the effects on seawater oxygen are relatively small in magnitude.
Tianfei Xue, Ivy Frenger, A. E. Friederike Prowe, Yonss Saranga José, and Andreas Oschlies
Biogeosciences, 19, 455–475, https://doi.org/10.5194/bg-19-455-2022, https://doi.org/10.5194/bg-19-455-2022, 2022
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The Peruvian system supports 10 % of the world's fishing yield. In the Peruvian system, wind and earth’s rotation bring cold, nutrient-rich water to the surface and allow phytoplankton to grow. But observations show that it grows worse at high upwelling. Using a model, we find that high upwelling happens when air mixes the water the most. Then phytoplankton is diluted and grows slowly due to low light and cool upwelled water. This study helps to estimate how it might change in a warming climate.
Shao-Min Chen, Ulf Riebesell, Kai G. Schulz, Elisabeth von der Esch, Eric P. Achterberg, and Lennart T. Bach
Biogeosciences, 19, 295–312, https://doi.org/10.5194/bg-19-295-2022, https://doi.org/10.5194/bg-19-295-2022, 2022
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Oxygen minimum zones in the ocean are characterized by enhanced carbon dioxide (CO2) levels and are being further acidified by increasing anthropogenic atmospheric CO2. Here we report CO2 system measurements in a mesocosm study offshore Peru during a rare coastal El Niño event to investigate how CO2 dynamics may respond to ongoing ocean deoxygenation. Our observations show that nitrogen limitation, productivity, and plankton community shift play an important role in driving the CO2 dynamics.
Paula Maria Salgado-Hernanz, Aurore Regaudie-de-Gioux, David Antoine, and Gotzon Basterretxea
Biogeosciences, 19, 47–69, https://doi.org/10.5194/bg-19-47-2022, https://doi.org/10.5194/bg-19-47-2022, 2022
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For the first time, this study presents the characteristics of primary production in coastal regions of the Mediterranean Sea based on satellite-borne observations for the period 2002–2016. The study concludes that there are significant spatial and temporal variations among different regions. Quantifying primary production is of special importance in the marine food web and in the sequestration of carbon dioxide from the atmosphere to the deep waters.
Samu Elovaara, Eeva Eronen-Rasimus, Eero Asmala, Tobias Tamelander, and Hermanni Kaartokallio
Biogeosciences, 18, 6589–6616, https://doi.org/10.5194/bg-18-6589-2021, https://doi.org/10.5194/bg-18-6589-2021, 2021
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Dissolved organic matter (DOM) is a significant carbon pool in the marine environment. The composition of the DOM pool, as well as its interaction with microbes, is complex, yet understanding it is important for understanding global carbon cycling. This study shows that two phytoplankton species have different effects on the composition of the DOM pool and, through the DOM they produce, on the ensuing microbial community. These communities in turn have different effects on DOM composition.
Yuan Dong, Qian P. Li, Zhengchao Wu, Yiping Shuai, Zijia Liu, Zaiming Ge, Weiwen Zhou, and Yinchao Chen
Biogeosciences, 18, 6423–6434, https://doi.org/10.5194/bg-18-6423-2021, https://doi.org/10.5194/bg-18-6423-2021, 2021
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Temporal change of plankton growth and grazing are less known in the coastal ocean, not to mention the relevant controlling mechanisms. Here, we performed monthly size-specific dilution experiments outside a eutrophic estuary over a 1-year cycle. Phytoplankton growth was correlated to nutrients and grazing mortality to total chlorophyll a. A selective grazing on small cells may be important for maintaining high abundance of large-chain-forming diatoms in this eutrophic system.
Kiefer O. Forsch, Lisa Hahn-Woernle, Robert M. Sherrell, Vincent J. Roccanova, Kaixuan Bu, David Burdige, Maria Vernet, and Katherine A. Barbeau
Biogeosciences, 18, 6349–6375, https://doi.org/10.5194/bg-18-6349-2021, https://doi.org/10.5194/bg-18-6349-2021, 2021
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We show that for an unperturbed cold western Antarctic Peninsula fjord, the seasonality of iron and manganese is linked to the dispersal of metal-rich meltwater sources. Geochemical measurements of trace metals in meltwaters, porewaters, and seawater, collected during two expeditions, showed a seasonal cycle of distinct sources. Finally, model results revealed that the dispersal of surface meltwater and meltwater plumes originating from under the glacier is sensitive to katabatic wind events.
Jenny Hieronymus, Kari Eilola, Malin Olofsson, Inga Hense, H. E. Markus Meier, and Elin Almroth-Rosell
Biogeosciences, 18, 6213–6227, https://doi.org/10.5194/bg-18-6213-2021, https://doi.org/10.5194/bg-18-6213-2021, 2021
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Dense blooms of cyanobacteria occur every summer in the Baltic Proper and can add to eutrophication by their ability to turn nitrogen gas into dissolved inorganic nitrogen. Being able to correctly estimate the size of this nitrogen fixation is important for management purposes. In this work, we find that the life cycle of cyanobacteria plays an important role in capturing the seasonality of the blooms as well as the size of nitrogen fixation in our ocean model.
Tom Hull, Naomi Greenwood, Antony Birchill, Alexander Beaton, Matthew Palmer, and Jan Kaiser
Biogeosciences, 18, 6167–6180, https://doi.org/10.5194/bg-18-6167-2021, https://doi.org/10.5194/bg-18-6167-2021, 2021
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The shallow shelf seas play a large role in the global cycling of CO2 and also support large fisheries. We use an autonomous underwater vehicle in the central North Sea to measure the rates of change in oxygen and nutrients.
Using these data we determine the amount of carbon dioxide taken out of the atmosphere by the sea and measure how productive the region is.
These observations will be useful for improving our predictive models and help us predict and adapt to a changing ocean.
Puthenveettil Narayana Menon Vinayachandran, Yukio Masumoto, Michael J. Roberts, Jenny A. Huggett, Issufo Halo, Abhisek Chatterjee, Prakash Amol, Garuda V. M. Gupta, Arvind Singh, Arnab Mukherjee, Satya Prakash, Lynnath E. Beckley, Eric Jorden Raes, and Raleigh Hood
Biogeosciences, 18, 5967–6029, https://doi.org/10.5194/bg-18-5967-2021, https://doi.org/10.5194/bg-18-5967-2021, 2021
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Upwelling in the coastal ocean triggers biological productivity and thus enhances fisheries. Therefore, understanding the phenomenon of upwelling and the underlying mechanisms is important. In this paper, the present understanding of the upwelling along the coastline of the Indian Ocean from the coast of Africa all the way up to the coast of Australia is reviewed. The review provides a synthesis of the physical processes associated with upwelling and its impact on the marine ecosystem.
Gaël Many, Caroline Ulses, Claude Estournel, and Patrick Marsaleix
Biogeosciences, 18, 5513–5538, https://doi.org/10.5194/bg-18-5513-2021, https://doi.org/10.5194/bg-18-5513-2021, 2021
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The Gulf of Lion shelf is one of the most productive areas in the Mediterranean. A model is used to study the mechanisms that drive the particulate organic carbon (POC). The model reproduces the annual cycle of primary production well. The shelf appears as an autotrophic ecosystem with a high production and as a source of POC for the adjacent basin. The increase in temperature induced by climate change could impact the trophic status of the shelf.
Alireza Merikhi, Peter Berg, and Markus Huettel
Biogeosciences, 18, 5381–5395, https://doi.org/10.5194/bg-18-5381-2021, https://doi.org/10.5194/bg-18-5381-2021, 2021
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The aquatic eddy covariance technique is a powerful method for measurements of solute fluxes across the sediment–water interface. Data measured by conventional eddy covariance instruments require a time shift correction that can result in substantial flux errors. We introduce a triple O2 sensor eddy covariance instrument that by design eliminates these errors. Deployments next to a conventional instrument in the Florida Keys demonstrate the improvements achieved through the new design.
Jiatang Hu, Zhongren Zhang, Bin Wang, and Jia Huang
Biogeosciences, 18, 5247–5264, https://doi.org/10.5194/bg-18-5247-2021, https://doi.org/10.5194/bg-18-5247-2021, 2021
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In situ observations over 42 years were used to explore the long-term changes to low-oxygen conditions in the Pearl River estuary. Apparent expansion of the low-oxygen conditions in summer was identified, primarily due to the combined effects of increased anthropogenic inputs and decreased sediment load. Large areas of severe low-oxygen events were also observed in early autumn and were formed by distinct mechanisms. The estuary seems to be growing into a seasonal, estuary-wide hypoxic zone.
Indah Ardiningsih, Kyyas Seyitmuhammedov, Sylvia G. Sander, Claudine H. Stirling, Gert-Jan Reichart, Kevin R. Arrigo, Loes J. A. Gerringa, and Rob Middag
Biogeosciences, 18, 4587–4601, https://doi.org/10.5194/bg-18-4587-2021, https://doi.org/10.5194/bg-18-4587-2021, 2021
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Organic Fe speciation is investigated along a natural gradient of the western Antarctic Peninsula from an ice-covered shelf to the open ocean. The two major fronts in the region affect the distribution of ligands. The excess ligands not bound to dissolved Fe (DFe) comprised up to 80 % of the total ligand concentrations, implying the potential to solubilize additional Fe input. The ligands on the shelf can increase the DFe residence time and fuel local primary production upon ice melt.
Melissa R. McCutcheon, Hongming Yao, Cory J. Staryk, and Xinping Hu
Biogeosciences, 18, 4571–4586, https://doi.org/10.5194/bg-18-4571-2021, https://doi.org/10.5194/bg-18-4571-2021, 2021
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We used 5+ years of discrete samples and 10 months of hourly sensor measurements to explore temporal variability and environmental controls on pH and pCO2 at the Aransas Ship Channel. Seasonal and diel variability were both present but small compared to other regions in the literature. Despite the small tidal range, tidal control often surpassed biological control. In comparison with sensor data, discrete samples were generally representative of mean annual and seasonal carbonate chemistry.
Kai G. Schulz, Eric P. Achterberg, Javier Arístegui, Lennart T. Bach, Isabel Baños, Tim Boxhammer, Dirk Erler, Maricarmen Igarza, Verena Kalter, Andrea Ludwig, Carolin Löscher, Jana Meyer, Judith Meyer, Fabrizio Minutolo, Elisabeth von der Esch, Bess B. Ward, and Ulf Riebesell
Biogeosciences, 18, 4305–4320, https://doi.org/10.5194/bg-18-4305-2021, https://doi.org/10.5194/bg-18-4305-2021, 2021
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Upwelling of nutrient-rich deep waters to the surface make eastern boundary upwelling systems hot spots of marine productivity. This leads to subsurface oxygen depletion and the transformation of bioavailable nitrogen into inert N2. Here we quantify nitrogen loss processes following a simulated deep water upwelling. Denitrification was the dominant process, and budget calculations suggest that a significant portion of nitrogen that could be exported to depth is already lost in the surface ocean.
Heiner Dietze and Ulrike Löptien
Biogeosciences, 18, 4243–4264, https://doi.org/10.5194/bg-18-4243-2021, https://doi.org/10.5194/bg-18-4243-2021, 2021
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In recent years fish-kill events caused by oxygen deficit have been reported in Eckernförde Bight (Baltic Sea). This study sets out to understand the processes causing respective oxygen deficits by combining high-resolution coupled ocean circulation biogeochemical modeling, monitoring data, and artificial intelligence.
Jens A. Hölemann, Bennet Juhls, Dorothea Bauch, Markus Janout, Boris P. Koch, and Birgit Heim
Biogeosciences, 18, 3637–3655, https://doi.org/10.5194/bg-18-3637-2021, https://doi.org/10.5194/bg-18-3637-2021, 2021
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The Arctic Ocean receives large amounts of river water rich in terrestrial dissolved organic matter (tDOM), which is an important component of the Arctic carbon cycle. Our analysis shows that mixing of three major freshwater sources is the main factor that regulates the distribution of tDOM concentrations in the Siberian shelf seas. In this context, the formation and melting of the land-fast ice in the Laptev Sea and the peak spring discharge of the Lena River are of particular importance.
Jaard Hauschildt, Soeren Thomsen, Vincent Echevin, Andreas Oschlies, Yonss Saranga José, Gerd Krahmann, Laura A. Bristow, and Gaute Lavik
Biogeosciences, 18, 3605–3629, https://doi.org/10.5194/bg-18-3605-2021, https://doi.org/10.5194/bg-18-3605-2021, 2021
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In this paper we quantify the subduction of upwelled nitrate due to physical processes on the order of several kilometers in the coastal upwelling off Peru and its effect on primary production. We also compare the prepresentation of these processes in a high-resolution simulation (~2.5 km) with a more coarsely resolved simulation (~12 km). To do this, we combine high-resolution shipboard observations of physical and biogeochemical parameters with a complex biogeochemical model configuration.
Samantha A. Siedlecki, Darren Pilcher, Evan M. Howard, Curtis Deutsch, Parker MacCready, Emily L. Norton, Hartmut Frenzel, Jan Newton, Richard A. Feely, Simone R. Alin, and Terrie Klinger
Biogeosciences, 18, 2871–2890, https://doi.org/10.5194/bg-18-2871-2021, https://doi.org/10.5194/bg-18-2871-2021, 2021
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Future ocean conditions can be simulated using projected trends in fossil fuel use paired with Earth system models. Global models generally do not include local processes important to coastal ecosystems. These coastal processes can alter the degree of change projected. Higher-resolution models that include local processes predict modified changes in carbon stressors when compared to changes projected by global models in the California Current System.
Erik Jacobs, Henry C. Bittig, Ulf Gräwe, Carolyn A. Graves, Michael Glockzin, Jens D. Müller, Bernd Schneider, and Gregor Rehder
Biogeosciences, 18, 2679–2709, https://doi.org/10.5194/bg-18-2679-2021, https://doi.org/10.5194/bg-18-2679-2021, 2021
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We use a unique data set of 8 years of continuous carbon dioxide (CO2) and methane (CH4) surface water measurements from a commercial ferry to study upwelling in the Baltic Sea. Its seasonality and regional and interannual variability are examined. Strong upwelling events drastically increase local surface CO2 and CH4 levels and are mostly detected in late summer after long periods of impaired mixing. We introduce an extrapolation method to estimate regional upwelling-induced trace gas fluxes.
Yangyang Zhao, Khanittha Uthaipan, Zhongming Lu, Yan Li, Jing Liu, Hongbin Liu, Jianping Gan, Feifei Meng, and Minhan Dai
Biogeosciences, 18, 2755–2775, https://doi.org/10.5194/bg-18-2755-2021, https://doi.org/10.5194/bg-18-2755-2021, 2021
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In situ oxygen consumption rates were estimated for the first time during destruction of coastal hypoxia as disturbed by a typhoon and its reinstatement in the South China Sea off the Pearl River estuary. The reinstatement of summer hypoxia was rapid with a comparable timescale with that of its initial disturbance from frequent tropical cyclones, which has important implications for better understanding the intermittent nature of coastal hypoxia and its prediction in a changing climate.
Dylan R. Brown, Humberto Marotta, Roberta B. Peixoto, Alex Enrich-Prast, Glenda C. Barroso, Mario L. G. Soares, Wilson Machado, Alexander Pérez, Joseph M. Smoak, Luciana M. Sanders, Stephen Conrad, James Z. Sippo, Isaac R. Santos, Damien T. Maher, and Christian J. Sanders
Biogeosciences, 18, 2527–2538, https://doi.org/10.5194/bg-18-2527-2021, https://doi.org/10.5194/bg-18-2527-2021, 2021
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Hypersaline tidal flats (HTFs) are coastal ecosystems with freshwater deficits often occurring in arid or semi-arid regions near mangrove supratidal zones with no major fluvial contributions. This study shows that HTFs are important carbon and nutrient sinks which may be significant given their extensive coverage. Our findings highlight a previously unquantified carbon as well as a nutrient sink and suggest that coastal HTF ecosystems could be included in the emerging blue carbon framework.
Giulia Bonino, Elisa Lovecchio, Nicolas Gruber, Matthias Münnich, Simona Masina, and Doroteaciro Iovino
Biogeosciences, 18, 2429–2448, https://doi.org/10.5194/bg-18-2429-2021, https://doi.org/10.5194/bg-18-2429-2021, 2021
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Seasonal variations of processes such as upwelling and biological production that happen along the northwestern African coast can modulate the temporal variability of the biological activity of the adjacent open North Atlantic hundreds of kilometers away from the coast thanks to the lateral transport of coastal organic carbon. This happens with a temporal delay, which is smaller than a season up to roughly 500 km from the coast due to the intense transport by small-scale filaments.
Markus Diesing, Terje Thorsnes, and Lilja Rún Bjarnadóttir
Biogeosciences, 18, 2139–2160, https://doi.org/10.5194/bg-18-2139-2021, https://doi.org/10.5194/bg-18-2139-2021, 2021
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The upper 10 cm of the seafloor of the North Sea and Skagerrak contain 231×106 t of carbon in organic form. The Norwegian Trough, the deepest sedimentary basin in the studied area, stands out as a zone of strong organic carbon accumulation with rates on par with neighbouring fjords. Conversely, large parts of the North Sea are characterised by rapid organic carbon degradation and negligible accumulation. This dual character is likely typical for continental shelf sediments worldwide.
Arnaud Laurent, Katja Fennel, and Angela Kuhn
Biogeosciences, 18, 1803–1822, https://doi.org/10.5194/bg-18-1803-2021, https://doi.org/10.5194/bg-18-1803-2021, 2021
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CMIP5 and CMIP6 models, and a high-resolution regional model, were evaluated by comparing historical simulations with observations in the northwest North Atlantic, a climate-sensitive and biologically productive ocean margin region. Many of the CMIP models performed poorly for biological properties. There is no clear link between model resolution and skill in the global models, but there is an overall improvement in performance in CMIP6 from CMIP5. The regional model performed best.
Heejun Han, Jeomshik Hwang, and Guebuem Kim
Biogeosciences, 18, 1793–1801, https://doi.org/10.5194/bg-18-1793-2021, https://doi.org/10.5194/bg-18-1793-2021, 2021
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The main source of excess DOC occurring in coastal seawater off an artificial lake, which is enclosed by a dike along the western coast of South Korea, was determined using a combination of various biogeochemical tools including DOC and nutrient concentrations, stable carbon isotope, and optical properties (absorbance and fluorescence) of dissolved organic matter in two different seasons (March 2017 and September 2018).
Cited articles
Aguilar-Islas, A. M., Hurst, M. P., Buck, K. N., Sohst, B., Smith, G. J., Lohan, M. C., and Bruland, K. W.: Micro- and macronutrients in the southeastern Bering Sea: Insight into iron-replete and iron-depleted regimes, Prog. Oceanogr., 73, 99–126, 2007.
Andersson, A. J. and Mackenzie, F. T.: Shallow-water oceans: a source or sink for atmospheric CO2?, Front Ecol. Environ, {2}(7), 348–353, 2004.
Azova, N. V.: Primary productivity of the Pribilof-Bristol area of the Bering Sea, in: Moiseev, P. A., Soviet fisheries investigation in the northeastern Pacific, Part III. Pishchevaya Promyshlennost Publishing, Moscow, VNIRO Proceedings {53} and TINRO Proceedings, 52, 149–154, (in Russian), 1964.
Banse, K. and English, D. C.: Comparing phytoplankton seasonality in the eastern and western subarctic Pacific and the western Bering Sea, Prog. Oceanogr., 43, 235–288, 1999.
Bates, N. R.: Interannual variability of oceanic CO2 and biogeochemical properties in the western North Atlantic subtropical gyre. Deep-Sea Res. Pt. II {48}(8–9), 1507–1528, https://doi.org/10.1016/S0967-0645(00)00151-X, 2001.
Bates, N. R.: Air-sea CO2 fluxes and the continental shelf pump of carbon in the Chukchi Sea adjacent to the Arctic Ocean, J. Geophys. Res.,{111}, C10013, https://doi.org/10.1029/2005JC003083, 2006.
Bates, N. R. and Mathis, J. T.: The Arctic Ocean marine carbon cycle: evaluation of air-sea CO2 exchanges, ocean acidification impacts and potential feedbacks, Biogeosciences, 6, 2433–2459, https://doi.org/10.5194/bg-6-2433-2009, 2009.
Bates, N. R., Hansell, D. A., Carlson, C. A., and Gordon, L. I.: Distribution of CO2 species, estimates of net community production, and air-sea CO2 exchange in the Ross Sea polynya, J. Geophys. Res.-Ocean, {103}(C2), 2883–2896, 1998a.
Bates, N. R., Takahashi, T., Chipman, D. W., and Knap, A. H.: Variability of pCO2 on diel to seasonal timescales in the Sargasso Sea, J. Geophys. Res. {103}(15), 567–1558, 1998b.
Bates, N. R., Best M. H. P., and Hansell, D. A.: Spatio-temporal distribution of dissolved inorganic carbon and net community production in the Chukchi and Beaufort Seas, Deep-Sea Res. Pt. II, {52}(22–24), 3324–3343, https://doi.org/10.1016/j.dsr2.2005.10.003, 2005.
Bates, N. R., Pequignet, A. C., and Sabine, C. L.: Ocean carbon cycling in the Indian Ocean: II. Estimates of net community production, Global Biogeochem. Cy., {20}(3), GB3021, https://doi.org/10.1029/2005GB002492, 2006.
Bates, N. R., Pequignet, A. C., and Sabine, C. L.: Ocean carbon cycling in the Indian Ocean: 1. Spatiotemporal variability of inorganic carbon and air-sea CO2 gas exchange, Global Biogeochem. Cy., {20}(3), GB3020, https://doi.org/10.1029/2005GB002491, 2006.
Bates, N. R., Mathis, J. T., and Cooper, L.: Ocean acidification and biologically induced seasonality of carbonate mineral saturation states in the Western Arctic Ocean, J. Geophys. Res., 114, C11007, https://doi.org/10.1029/2008JC004862, 2009.
Bond, N. A., Overland, J. E., Spillane M., and Stabeno P.: Recent shifts in the state of the North Pacific, Geophys. Res. Lett., {30}(23), 2183, https://doi.org/10.1029/2003GL018597, 2003.
Bond, N. A. and Overland, J. E.: The importance of episodic weather events to the ecosystem of the Bering Sea shelf, Fish. Oceanogr., 14, 97–111, 2005.
Bryan, K. and Spelman, M. J.: The Ocean's Response to a CO2-Induced Warming, J. Geophys. Res., {90}(C6), 11679–11688, 1985.
Brzezinski, M. A.: The Si:C:N ratio of marine diatoms: Interspecific variability and the effect of some environmental variables, J. Phycol., 21, 347–357, 1985.
Chipman, D. W., Marra, J., and Takahashi, T.: Primary production at 47° N and 20 W in the North Atlantic Ocean: a comparison between the 14C incubation method and the mixed layer carbon budget, Deep-Sea Res., 40, 151–169, 1993.
Coachman, L. K. and Charnell, R. L.: On later water mass interaction – a case study, Bristol Bay, Alaska, J. Phys. Oceanogr., 9, 278–297, 1979.
Coachman, L. K.: Circulation, water masses, and fluxes on the southeastern Bering Sea shelf, Cont. Shelf Res., 5, 23–108, 1986.
Coachman, L. K. and Charnell, R. L.: On lateral water mass interaction–-a case study, Bristol Bay, Alaska, J. Phys. Oceanogr., {9}(2), 278–297, 1979.
Codispoti, L. A., Friederich, G. E., Iverson, R. L. and Hood, D.W.: Temporal changes in the inorganic carbon system of the southeastern Bering Sea during spring 1980, Nature, 296, 242–245, 1982.
Codispoti, L. A., Friederich, G. E., and Hood, D. W.: Variability in the inorganic carbon system over the southeastern Bering Sea shelf during spring 1980 and spring – summer 1981, Cont. Shelf Res., {5}(1–2), 133–160, 1986.
Coyle, K. O., Pinchuk, A. I., Eisner, L. B., and Napp, J. M.: Zooplankton species composition, abundance, and biomass on the eastern Bering Sea shelf during summer: The potential role of water-column stability and nutrients in structuring the zooplankton community, Deep Sea Res. Pt. II, 55, 1775–1791, 2008.
Denman, K. L. and Gargett A. E.: Time and space scales of vertical mixing and advection of phytoplankton in the upper ocean, Limnol. Oceanogr., {28}(5), 801–815, 1983.
Dickson, A. G., Sabine, C. L, and Christian, J. R.: Guide to Best Practices for Ocean CO2 measurements, PICES Special Publication, 3, 191 pp., 2007.
Eppley, R. W. and Peterson, B. J.: Particulate organic matter flux and planktonic new production in the deep ocean, Nature, 282, 677–680, 1979.
Francis, R. C., Hare, S. R., Hollowed, A. B., and Wooster, W. S.: Effects of interdecadal climate variability y on the oceanic ecosystems of the NE Pacific, Fish. Oceanogr., 7, 1–21, 1998.
Franks, P. J. S.: Sink or swim: accumulation of biomass at fronts. Mar. Ecol. Prog.-Ser., 82, 1–12, 1992.
Fujishima, Y., Ueda, K., Maruo, M., Nakayama, E., Tokutome, C., Hasegawa, H., Matsui, M., and Sohrin, Y.: Distribution of trace bioelements in the subarctic North Pacific Ocean and the Bering Sea, J. Oceanogr., 57, 261–273, 2001.
Fung, I. Y., Meyn, S. K., Tegen, I., Doney, S. C., John, J. G., and Bishop, J. K. B.: Iron supply and demand in the upper ocean, Global Biogeochem. Cy., 14, 281–291, 2000.
Gordon, L. I., Jennings Jr., J. C., Ross, A. A., Krest, J. M.: A suggested protocol for continuous automated analysis of seawater nutrients (phosphate, nitrate, nitrite and silicic acid) in the WOCE Hydrographic program and the Joint Global Ocean Fluxes Study.WOCE Operations Manual, vol. 3: The Observational Programme, Section 3.2: WOCE Hydrographic Programme, Part 3.1.3: WHP Operations and Methods.WHP Office ReportWHPO 91-1; WOCE Report No. 68/91. November, 1994, Revision 1, Woods Hole, MA, USA, 52 loose-leaf pages, 1993.
Graham, H. W. and Edwards, R. L.: The World biomass of marine fishes. In Heen, E. (ed.), Primary Production in the Sea, Plenum Press, New Jersey, pp 433–460, 1962.
Grebmeier, J. M., Overland, J. E., Moore, S. E., Farley, E. V., Carmack, E. C., Cooper, L. W., Frey, K. E., Helle, J. H., McLaughlin, F. A., and McNutt, S. L.: A major ecosystem shift in the northern Bering Sea. Science, 311, 1461–1464, 2006.
Grebmeier, J. M. and McRoy, C. P.: Pelagic-Benthic coupling on the shelf of the northern Bering and Chukchi Seas III. Benthic food supply and carbon cycling, Mar. Ecol. Prog.-Ser., 53, 79–91, 1989.
Hansell, D. A., Whitledge, T. E., and Goering, J. J.: Patterns of nitrate utilization and new production over the Bering-Chukchi shelf, Cont. Shelf Res., 13, 601–628, 1993.
Hansell, D. A., Bates, N. R. and Carlson, C. A.: Predominantly vertical losses of carbon from the surface layer of the Equatorial Pacific Ocean, Nature, 386, 59-61, 1997.
Hattori, A. and Goering, J. J.: Nutrient distributions and dynamics in the Eastern Bering Sea, in: Hood, D.W. and Calder, J. A., The eastern Bering Sea Shelf: Oceanogrphy and resources, Oceanography, {3}(3), 130 pp., 1981.
Hollowed, A. B., Hare, S. R., and Wooster, W. S.: Pacific-Basin climate variability and patterns of northeast Pacific marine fish production. Prog. Oceanogr., 49, 257–282, 2001.
Hunt Jr., G. L., Stabeno, P. J., Walters, G., Sinclair, E., Brodeu, R. D., Napp, J. M. and Bond, N. A.: Climate change and control of the southeastern Bering Sea pelagic ecosystem, Deep-Sea Res. Pt. II, 49, https://doi.org/S0967-0645(02)00321-1, 2002.
Hunt, G. L.,and Stabeno P. J.: Climate change and the control of energy flow in the southeastern Bering Sea, Prog. Oceanogr., 55, 5–22, 2002.
Hutchins, D. A. and Bruland, K. W.: Iron-limited diatom growth and Si:N uptake ratios in a coastal upwelling regime. Nature, 393, 591–564, 1998.
Ivanenkov, V. N.: Primary production in the Bering Sea, Trans. Inst. Oceanol. Acad. Sci. USSR, Moscow, 51, 36–56, (in Russian), 1961.
Kachel, N. B., Hunt, G., Salo, S. A., Schumacher, J. D., Stabeno, P. J., and Whitledge, T. E.: Characteristics of the Inner Front of the Southeastern Bering Sea, Deep Sea Res. Pt. II, 49, 5889–5909, 2002.
Karl, D. M., Tilbrook, B. D., and Tien, G.: Seasonal coupling of organic matter production and particle flux in the western Bransfield Strait, Antarctica, Deep-Sea Res., 38, 1097–1126, 1991.
Khen, G. V.: Oceanographic conditions and Bering Sea biological productivity, in: Proceedings of the International Symposium on the Biology and management of Walleye Pollock. Ancorage, AK: Alaska Sea Grant Rep., 89-1:79-94, 1988.
Kinder, T. H. and Coachman, L. K.: The front overlying the continental slope in the eastern Bering Sea, J. Geophys. Res., 83, 4551–4559, 1978.
Koike, I., Ogawa, H., Nagata, T., Fukuda, R., and Fukuda, H.: Silicate to nitrate ratio of the upper sub-arctic pacific and the bering sea basin in summer: its implication for phytoplankton dynamics, J. Oceanogr., 57, 253–260, 2001.
Koblentz-Mishke, O. I., Volkovinsky, V. V., and Kabanova, I. G.: Plankton primary production in the world ocean, Scientific Exploration of the South Pacific, 183–193, 1970.
Kruse, G. H.: Salmon run failures in 1997-1998: A link to anomalous ocean conditions?, Alaska Fishery Research Bulletin, {5}(1), 55–63, 1998.
Lee, K.: Global net community production estimated from the annual cycle of surface water total dissolved inorganic carbon, Limnol. Oceanogr., {46}(6), 1287–1297, 2001.
Lee, K., Karl, D. M., Wanninkhof, R., and Zhang, J. Z.: Global estimates of net carbon production in the nitrate-depleted tropical and subtropical oceans, Geophys. Res. Lett., {29}(19), 1907, https://doi.org/10.1029/2001GL014198, 2002.
Lovvorn, J. R., Cooper, L. W., Brooks, M. L., de Ruyck, C. C., Bump, J. K., and Grebmeier, J. M.: Organic matter pathways to zooplankton and benthos under pack ice in late winter and open water in late summer in the north-central Bering Sea, Mar. Ecol. Prog.-Ser., 291, 135–150, 2005.
Mackas, D. L., Denman, K .L., and Abbott, M. K.: Plankton patchiness: biology in the physical vernacular, Bull. Mar. Sci., 37, 652–674, 1985.
Macklin, S. A., Hunt Jr. G. L., and Overland, J. E.: Collaborative research on the pelagic ecosystem of the southeastern Bering Sea shelf, Deep-Sea Res. Pt. II, {49}(26), 5813–5819, 2002.
Maeda, T.: Relationship between annual fluctuation of oceanographic conditions and abundance of year classes of the yellow-fin sole in the eastern Bering Sea. In Fisheries Biological Production in the Subarctic Pacific Region. Hakodate, Japan: Hokkaido University, Special Volume, pp. 259–268, 1977.
Mathis, J. T., Bates, N. R., Hansell, D. A., and Babila, T.: Net community production in the northeastern Chukchi Sea, Deep-Sea Res. Pt. II, {56}(17), 1213–1222, https://doi.org/10.1016/j.dsr2.2008.10.017, 2009.
Mathis, J. T., Hansell, D. A., Kadko, D., Bates, N. R., and Cooper, L. W.: Determining net dissolved organic carbon production in the hydrographically complex western Arctic Ocean, Limnol. Oceanogr., {52}(5), 1789–1799, 2007.
McRoy, C. P. and Goering, J. J.: Annual budget of primary production of the Bering Sea, Marine Science Communications, 2, 255–267, 1976.
McRoy, C., Whitledge, T. E., Springer, A. M., Simpson, E. P.: The nitrate front in the Bering Sea: is this an iron curtain? Oral presentation abstract, http://www.aslo.org/meetings/aslomeetings.html, 2001.
Mizobata, K. and Saitoh, S.: Variability of Bering Sea eddies and primary productivity along the shelf edge during 1998–2000 using satellite multisensor remote sensing, J. Marine Syst., 50, 101–111, 2004.
Mizobata, K., Saitoh, S. I., Shiomoto, A., Miyamura, T., Shiga, N., Imai, K., Toratani, M., Kajiwara, Y., and Sasaoka, K.: Bering Sea cyclonic and anticyclonic eddies observed during summer 2000 and 2001 Prog. Oceanogr., 55, 65–75, 2002.
Moore, J. K., Doney, S. C., Glover, D. M., and Fung I. Y.: Iron cycling and nutrient-limitation patterns in surface waters of the World Ocean, Deep Sea Res. Pt. II, {49}(1–3), 463–507, 2001.
Motoda, S. and Minoda, T.: Plankton in the Bering Sea, edited by: Hood, D. and Kelley, E., Oceanography of the Bering Sea, University of Alaska, Fairbanks, pp 207–241, 1974.
Napp, J. M., and Hunt Jr., G. L.: Anomalous conditions in the southeastern Bering Sea, 1997: linkages among climate, weather, ocean, and biology, Fish. Oceanogr., {10}(1), 61–68, 2001.
Niebauer, H. J., Alexander, V., and Henrichs, S.: Physical and biological oceanographic interaction in the spring bloom at the Bering Sea marginal ice-edge zone, J. Geophys. Res., 95, 22229–22241, 1990.
Niebauer, H. J., Alexander V., and Henrichs S. M.: A time-series study of the spring bloom at the Bering Sea ice edge. I: Physical processes, chlorophyll and nutrient chemistry, Cont. Shelf Res., 15, 1859–1878, 1995.
Ohtani, K. and Azumaya, T.: Influence of interannual changes in ocean conditions on the abundance of walleye pollock ({Theragra chalcogramma}) in the eastern Bering Sea. Pp. 87-95 in North Pacific Workshop on Stock Assessment and management of Invertebrates, edited by: Beamish, R. J., Can Spec. Publ. Fish. Aquat. Sci., 92, 87–95, 2002.
Okkonen, S. R., Schmidt, G. M., Cokelet, E. D., and Stabeno, P. J.: Satellite and hydrographic observations of the Bering Sea "Green Belt", Deep-Sea Res. Pt. II, 51, 1033–1051, 2004.
Overland, J. E. and Stabeno, P.: Is the climate of the Bering Sea warming and affecting the ecosystem? EOS Trans., American Geophysical Union, 85, 309–316, 2004.
Parsons, T. R.: The impact of industrial fisheries on the trophic structure of marine ecosystems. In G.A. Polis and K.O. Winemiller (Eds.), Food webs: Integration of patterns and dynamics (pp. 352–357), New York, Chapman and Hall, 1996.
Pease, C. H.: Eastern Bering Sea ice processes, Mon. Weather Rev., 108, 2015–2023, 1980.
Rho, T., Whitledge, T. E., and Goering, J. J.: Interannual variations of nutrients and primary production over the southeastern Bering Sea shelf during the spring of 1997, 1998 and 1999, Oceanology, 45, 376–390, 2005.
Rho, T. and Whiledge, T. E.: Characteristics of seasonal and spatial variations of primary production over the southeastern Bering Sea shelf, Cont. Shelf Res., 27, 2556–2569, 2007.
Roots, E. F.: Climate Change: High Latitude Regions, Climatic Change, 15, 223–253, 1989.
Rudels, B.: The thermohaline circulation of the Arctic Ocean and the Greenland Sea, Philos. Trans. R. Soc. Lond., A. 352, 287–299, 1995.
Saino, T., Miyata, K., and Haqttori, A.: Primary productivity in the Bering and Chukchi Seas and in the norther North Pacific in summer 1978, Bull. Plankton Soc. Jpn., 26, 96–103, 1979.
Saitoh, S., Iida, T., and Sasaoka, K.: A description of temporal and spatial satellite multi-sensor remote sensing. Prog. Oceanogr., {55}(1–2), 131–146, 2002.
Sambrotto, R. N., and Goering, J. J.: Interannual variability of phytoplankton and zooplankton production on the southeast Bering Sea shelf, edited by: Wooster, W. S., From Year-to-Year: Interannual Variability of the Environment and Fisheries of the Gulf of Alaska and the Eastern Bering Sea, Washington State Sea Grant, Seattle, WA, pp. 161–177, 1983.
Sambrotto, R. N., Mordy, C., Zeeman, S. I., Stabeno, P. J., and Macklin, S. A.: Physical forcing and nutrient conditions associated with patterns of Chl a and phytoplankton productivity in the southeastern Bering Sea during summer, Deep Sea Res. Pt.II, 55, 1745–1760, 2008.
Sambrotto, R. N., Niebauer, H. J., Goering, J. J., and Iverson, R. L.: Relationships among vertical mixing, nitrate uptake, and phytoplankton growth during the spring bloom in the southeast Bering Sea middle shelf, Cont. Shelf Res., 5, 161–198, 1986.
Sambrotto, R. N., Savidge, G., Robinson, C., Boyd, P., Takahashi, T., Karl, D. M., Langdon, C., Chipman, D., Marra, J., and Codispoti, L.: Elevated consumption of carbon relative to nitrogen in the surface ocean, Nature, 363, 248–250, 1993.
Sapozhnikov, V. V. and Naletova, I. A.: Studies of the biohydrochemical structure of the euphotic layer and primary production in the Bering Sea, Oceanology, {35}(2), 189–196, 1995.
Scheffer, M., Carpenter, S., Foley, J. A., Folke, C., and Walker, B.: Catastrophic shifts in ecosystems, Nature, {413}(6856), 591–96, 2001.
Schumacher, J. D. and Reed, R. K.: Characteristics of currents near the continental slope of the eastern Bering Sea, J. Geophys. Res., 97, 9423–9433, 1992.
Schumacher, J. D., Bond, N. A., Brouder, R. D., Livingston, P. A., Napp, J. M. and Stabeno, P. J.: Climate changes in the southeastern Bering Sea and some consequences for biota. In Large marine ecosystems of the world: Trends in exploitation, Protection and Research, edited by: Hemple, G., Sherman, K., Elsevier, Amsterdam, 2002.
Schumacher, J. D. and Stabeno, P. J.: The continental Shelf of the Bering Sea, in: The Sea: Vol. 11 – The Global Coastal Ocean: Regional Studies and Synthesis, John Wiley and Sons, Inc., New York, NY, 789–822, 1998.
Schumacher, J. D. and Stabeno, P. J.: Ubiquitous eddies of the eastern Bering Sea and their coincidence with concentrations of larval pollock, Fish. Oceanogr., 3, 182–190, 1994.
Schumacher, J. D. and Alexander, V.: Variability and role of the physical environment in the Bering Sea ecosystem, in: Dynamics of the Bering Sea, edited by: Loughlin, T.R. and Ohtani, K., University of Alaska Sea Grant, Fairbanks, Alaska, AK-SG-99-03, pp. 147–160, 1999.
Serreze, M. C. and Francis, J. A.: The Arctic amplification debate, Climate Change, 76, 241–64, 2006.
Simpson, E. and McRoy, C.: Model evidence of a Bering Sea iron curtain. Oral presentation abstract, http://www.aslo.org/meetings/aslomeetings.html, 1999.
Sorokin, Yu. I.: Data on primary production in the Bering Sea and adjacent Norther Pacific, J. Plankton Res., {21}(4), 615–636, 1999.
Sorokin, Yu. I. and Mikheev, V. N.: Characteristics of the Peruvian upwelling ecosystem, Hydrobiologia, 62, 165–189, 1979.
Sorokin, Yu. I.: On the methodology of primary production measurements in the sea with the use of 14C. Trans., USSR, Hydrobiol. Soc., Moscow, 10, 235–254, 1960.
Springer, A. M. and McRoy, C. P.: The paradox of pelagic food webs in the northern Bering Sea–-III. Patterns of primary production, Cont. Shelf Res., 13, 575–599, 1993.
Springer, A. M., McRoy, C. P., and Flint, M. V.: The Bering Sea Green Belt: shelf-edge processes and ecosystem production, Fish. Oceanogr., {5}(3–4), 205–223, 1996.
Springer, A. M.: Is it all climate change? Why marine bird and mammal populations fluctuate in the North Pacific, in: Biotic impacts of extratropical climate change in the Pacific. 'Aha Huliko'a Proceedings Hawaiian Winter Workshop, University of Hawaii, pp 109–119, 1998.
Stabeno, P. J., Kachel, N. B., Sullivan, P., and Whitledge, T. E.: Variability along the 70 m isobath of the southeastern Bering Sea, Deep Sea Res. Pt. II, 49, 5931–5943, 2002.
Stabeno, P. J. and van Meurs, P.: Evidence of episodic on-shelf flow in the southeastern Bering Sea, J. Geophys. Res., {104}(29), 715–729, 1999.
Stabeno, P. J., and Hunt Jr., G. L.: Overview of the inner front and southeast Bering Sea carrying capacity programs, Deep-Sea Res. Pt. II, {49}(26), 6157-6168, 2002.
Stabeno, P. J., Hunt Jr., G. L., Napp, J. M., and Schumacher, J. D.: Physical forcing of ecosystem dynamics on the Bering Sea shelf, in: Robinson, A.R. and Brink, K., The Sea vol. 14B, The Global Coastal Ocean: Interdisciplinary Regional Studies and Syntheses, Harvard University Press, 2006.
Stabeno, P. J., Schumacher, J. D., and Ohtani, K.: The physical oceanography of the Bering Sea, in: Dynamics of the Bering Sea: A Summary of Physical, Chemical, and Biological Characteristics, and a Synopsis of Research on the Bering Sea, edited by: Loughlin, T. R. and Ohtani, K., North Pacific Marine Science Organization (PICES), Univ. of Alaska Sea Grant, AK-SG-99-03, 1–28, 1999.
Stockwell, D. A., Whitledge, T. E., Zeeman, S. I., Coyle, K. O., Napp, J. M., Brodeur, R. D., Pinchuk, A. I., and Hunt Jr. G. L.: Anomalous conditions in the south-eastern Bering Sea, 1997: nutrients, phytoplankton and zooplankton, Fish. Oceanogr., 10, 99–116, 2001
Suzuki, K., Liu, H., Saino, T., Obata, H., Takano, M., Okamura, K., Sohrin, Y., and Fujishima, Y.: East-west gradients in the photosynthetic potential of phytoplankton and iron concentration in the subarctic Pacific Ocean during early summer, Limnol. Oceanogr., 46, 1581–1594, 2002.
Takahashi, T., Sutherland, S. C., Sweeney, C., Poisson, A., Metzl, N., Tilbrook, B., Bates, N., Wanninkhof, R., Feely, R. A., Sabine, C., Olafsson, J., and Nojiri, Y.: Global sea – air CO2 flux based on climatological surface ocean pCO2, and seasonal biological and temperature effects{. Deep-Sea Res. Pt. II}, {49}(9–10), 1601–1622, https://doi.org/10.1016/S0967-0645(02)00003-6, 2002.
Takahashi, T., Sutherland, S. C., Wanninkhof, R., Sweeney, C., Feely, R. A., Chipman, D. W., Hales, B., Friederich, G., Chavez, F., Watson, A., Bakker, D. C. E., Schuster, U., Metzl, N., Yoshikawa-Inoue, H., Ishii, M., Midorikawa, Nojiri, Y., Kortzinger, A., Steinhoff, T., Hoppema, M., Olafsson, J., Arnarson, T. S., Tilbrook, B., Johannessen, T., Olsen, A., Bellerby, R., Wong, C. S., Delille, B., Bates, N. R., and de Baar, H. J. W.: Climatological mean and decadal change in surface ocean pCO2, and net sea-air CO2 flux over the global oceans, Deep-Sea Res. Pt. II, {56}(8–10), 554–577, https://doi.org/10.1016/j.dsr2.2008.12.009, 2009.
Takata, H., Kuma, K., Iwade, S., and Isoda, Y.: Comparative vertical distributions of iron in the Japan Sea, the Bering Sea, and the western North Pacific Ocean, J. Geophys. Res., 110, CO7004, https://doi.org/ 10.1029/2004JC002783, 2005.
Tsiban, A. V. and Korsak, M. N.: Primary and microbial production in the Bering Sea. Biol. Sea (Valdivostok), 6, 15–21, (in Russian), 1987.
Turner, J., Overland, J. E., and Walsh, J. E.: An Arctic and Antarctic perspective on recent climate change, Int. J. Climatol., 27, 277–293, 2007.
Varela, D. E. and Harrison, P. J.: Seasonal variability in the nitrogenous nutrition of phytoplankton in the northeastern subarctic Pacific Ocean, Deep-Sea Res. Pt. II, 46, 2505–2538, 1999.
Walsh, J. E. and Johnson, C. M.: An analysis of Arctic sea ice fluctuations, 1953–1977, J. Phys. Oceanogr., 9, 580–591, 1979.
Weiss, R. F., Ostlund, H. G., and Craig, H.: Geochemical studies of the Weddell Sea, Deep-Sea Res., 26, 1093–1120, 1979.
Whitledge, T. E., Bidigare, R. E., Zeeman, S. I., Sambrotto, R. N., Rascigno, P. F., Jensen, P. R., Brooks, J. M., Trees, C., and Veidt, D. M.: Biological measurements and related chemical features in Soviet and United States regions of the Bering Sea, Cont. Shelf Res., 8, 1299–1319, 1988.
Whitledge, T. E., Reeburgh, W. S., and Walsh, J. J.: Seasonal inorganic nitrogen distributions and dynamics in the southeastern Bering Sea, Cont. Shelf Res. 5, 109–132, 1986.
Whitledge, T. E. and Luchin V. A.: Summary of chemical distributions and dynamics in the Bering Sea, edited by: Loughlin, T. R. and Ohtani, K., Dynamics of the Bering Sea, University of Alaska Sea Grant, Fairbanks, AK, pp. 217–249, 1999.
Williams, P. J.: On the definition of plankton production terms, edited by: Li, W. K. W. and Maestrini, S. Y., Measurements of Primary Production from the Molecular to the Global Scale, ICES Mar. Sci. Symp., 197, 9–19, 1993.
Wong, C. S., Waser, N. A. D., Nojiri, Y., Whitney, F. A., Page, J. S. and Zeng, J.: Seasonal cycles of nutrients and dissolved inorganic carbon at high and mid latitudes in the North Pacific Ocean during the Skaugran cruises: determination of new production and nutrient uptake ratios, Deep-Sea Res. Pt. II, 49, 5317–5338, 2002.
Wyllie-Escheveria, T. and Wooster, W. S.: Year-to-year variations in Bering Sea ice cover and some consequences for fish distributions, Fisheries Oceangraphy, {7}(2), 159–170, 1998.
Wyllie-Escheveria, T.: Seasonal sea ice, the cold pool and gadid distribution on the Bering Sea shelf. Ph.D. dissertation, 281 pp, Univ. Of Alaska, Fairbanks, 1995.
Yager, P. L., Wallace, D. W. R., Johnson, K. M., Smith, W. O., Minnett, P. J., and Deming, J. W.: The Northeast Water Polynya as an atmospheric CO2 sink: A seasonal rectification hypothesis, J. Geophys. Res., 100, 4389–4398, 1995.
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