Temporal responses of coastal hypoxia to nutrient loading and physical controls

Kemp, W. Michael; Testa, Jeremy M.; Conley, Daniel J.; Gilbert, Denis; Hagy, James D.

doi:10.5194/bg-6-2985-2009

Cited by 363 publications

(279 citation statements)

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“…Mesoscale intrusions of subsurface suboxic waters from the Rim Current of the Black Sea general circulation system also episodically modulate the near-bottom oxygen structure of northwestern shelf (Black Sea Commission, 2008). Longterm observations show that coastal hypoxia off large river mouths and in estuaries/bays has an important seasonal (Rabalais et al, 2001) and/or inter-annual component (Gilbert et al, 2005;Kemp et al, 2009) that can be related to climate variability as well. For example, the annual discharge of the Mississippi River is predicted to increase by 20% if the concentration of atmospheric CO 2 doubles, and nutrient load would increase as well, which will induce stronger stratification and more serious eutrophication, followed by an ever intensified hypoxia on the Louisiana Continental Shelf (Rabalais and ).…”

Section: Hypoxia Off River Mouths and In Estuariesmentioning

confidence: 99%

“…Comparative studies also clarify how biogeochemical dynamics defines the magnitude and consequences of coastal hypoxia. High-resolution measurements have enabled the establishment of cross-boundary and mechanistic understanding of the emergent, evolving and declining phases of coastal hypoxia (Kemp et al, 2009). The episodic, periodic (i.e.…”

Section: Understanding the Causes Of Coastal Hypoxiamentioning

confidence: 99%

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Natural and human-induced hypoxia and consequences for coastal areas: synthesis and future development

et al. 2010

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Abstract. Hypoxia has become a world-wide phenomenon in the global coastal ocean and causes a deterioration of the structure and function of ecosystems. Based on the collective contributions of members of SCOR Working Group #128, the present study provides an overview of the major aspects of coastal hypoxia in different biogeochemical provinces, including estuaries, coastal waters, upwelling areas, fjords and semi-enclosed basins, with various external forcings, ecosysCorrespondence to: J. Zhang (jzhang@sklec.ecnu.edu.cn) tem responses, feedbacks and potential impact on the sustainability of the fishery and economics. The obvious external forcings include freshwater runoff and other factors contributing to stratification, organic matter and nutrient loadings, as well as exchange between coastal and open ocean water masses. Their different interactions set up mechanisms that drive the system towards hypoxia. Coastal systems also vary in their relative susceptibility to hypoxia depending on their physical and geographic settings. It is understood that coastal hypoxia has a profound impact on the sustainability of ecosystems, which can be seen, for example, by the change in the food-web structure and system function; other Published by Copernicus Publications on behalf of the European Geosciences Union. 1444 J. Zhang et al.: Natural and human-induced hypoxia and consequences for coastal areas influences include compression and loss of habitat, as well as changes in organism life cycles and reproduction. In most cases, the ecosystem responds to the low dissolved oxygen in non-linear ways with pronounced feedbacks to other compartments of the Earth System, including those that affect human society. Our knowledge and previous experiences illustrate that there is a need to develop new observational tools and models to support integrated research of biogeochemical dynamics and ecosystem behavior that will improve confidence in remediation management strategies for coastal hypoxia.

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Section: Hypoxia Off River Mouths and In Estuariesmentioning

confidence: 99%

Section: Understanding the Causes Of Coastal Hypoxiamentioning

confidence: 99%

Natural and human-induced hypoxia and consequences for coastal areas: synthesis and future development

et al. 2010

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“…Inflow of nutrients, especially nitrogen (N), stimulates primary production in the estuary, occasionally leading to a rise in frequency and intensity of harmful algal blooms (Weise et al 2002;Bricker et al 2008) which induce massive mortality of marine fish, birds and mammals . Organic carbon exported from the watershed and plankton produced within the estuary eventually sediments into deep estuarine waters, where enhanced microbial activity induces hypoxia and anoxia (Kemp et al 2009). Median rates of oxygen decline are more severe in a 30 km band near the coast than in the open ocean ([100 km from the coast) (Gilbert et al 2010) which also exerts a range of negative effects on marine coastal ecosystems (Diaz and Rosenberg 2008).…”

Section: Introductionmentioning

confidence: 99%

Hydrological and biological processes modulate carbon, nitrogen and phosphorus flux from the St. Lawrence River to its estuary (Quebec, Canada)

et al. 2017

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Increased flux of carbon and nutrients from human activities in river basins were linked to acidification and deepwater hypoxia in estuaries and coastal areas worldwide. Annual loads (1995)(1996)(1997)(1998)(1999)(2000)(2001)(2002)(2003)(2004)(2005)(2006)(2007)(2008)(2009)(2010)(2011) of suspended particulate matter (SPM), dissolved organic carbon (DOC), total nitrogen (TN) and total phosphorus (TP) were assessed at the Lake Ontario inlet of the St. Lawrence River (SLR) (7110 m 3 s -1 ) and its estuarine outlet at Québec City (12,090 m 3 s -1 ). Internal loads from the Ottawa River (1950 m 3 s -1 ), seventeen other tributaries, urban wastewaters, atmospheric deposition and erosion were also estimated. Erosion (65% of SPM, 29% of TP), inflow from Lake Ontario (42% of DOC, 47% of TN) and Ottawa River (28% of DOC) contributed important flux to the estuary. Loads from other tributaries (20 and 27% of TN and TP at Quebec City) largely exceeded municipal sources (6% of exported TN and TP) and require future remediation. Aquatic plants fixed 277,000 t of C, 49,000 t of N and 7000 t of P (May-Sept.), delaying the nutrient flux to the estuary and turning the SLR into a nutrient sink over summers of lowest discharge. Degradation of exported organic C could consume 5.4-7.1 million t O 2 year -1 in the estuary whereas SLR flux of N and P represent 31-47% and 7-14% of total annual estuarine flux, respectively. Carbon and Nitrogen flux from freshwaters partly explain the decline in pH and oxygen concentrations in deep estuarine waters thus highlighting the need to reduce diffuse sources of nutrients in the entire watershed.

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“…Hypoxia occurs naturally in many coastal environments with restricted circulation, such as fjords and inland seas, but hypoxia in locations with less restricted circulation both offshore (e.g., California Current, Benguela Current) and near-shore (Diaz and Rosenberg, 2008;Gilbert et al, 2010) is increasingly being reported. This may reflect changes in ocean circulation (Gilbert et al, 2005) or increased eutrophication (Kemp et al, 2009). Shallow or seasonally stratified water columns can be ventilated by vertical mixing events, which may prevent hypoxia from becoming persistent (Rabalais et al, 2001).…”

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Acidification of Lower St. Lawrence Estuary Bottom Waters

et al. 2011

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Accumulation of metabolic CO 2 can acidify marine waters above and beyond the ongoing acidification of the ocean by anthropogenic CO 2 . The impact of respiration on carbonate chemistry and pH is most acute in hypoxic and anoxic basins, where metabolic CO 2 accumulates to high concentrations. The bottom waters of the Lower St. Lawrence Estuary (LSLE), where persistently severe hypoxia has developed over the last 80 years, is one such case. We have reconstructed the evolution of pH in the bottom waters from historical and recent data, and from first principles relating the stoichiometry of CO 2 produced to oxygen consumed during microbial degradation of organic matter. Based on the value of the atmospheric partial pressure of CO 2 that best reproduces the preformed dissolved inorganic carbon concentration in the bottom waters, we estimate the average ventilation age of the bottom waters to be 16 ± 3 years. The pH of the bottom waters has decreased by 0.2 to 0.3 over the last 75 years, which is four to six times greater than can be attributed to the uptake of anthropogenic CO 2 . The pH decrease is accompanied by a decline in the saturation state with respect to both calcite and aragonite. As of 2007, bottom waters in the LSLE are slightly supersaturated with respect to calcite (Ω c ≈ 1.06 ± 0.04) but are strongly undersaturated with respect to aragonite (Ω a ≈ 0.67 ± 0.03).RÉSUMÉ L'accumulation de CO 2 métabolique acidifie l'eau de mer au-delà de ce qui est généré par l'ajout de CO 2 anthropique. L'impact de la respiration sur la spéciation des espèces carbonatées en solution et du pH est plus marqué dans les bassins hypoxiques et anoxiques où le CO 2 métabolique atteint de fortes concentrations. Dans l'estuaire maritime du Saint-Laurent (EMSL), des eaux profondes sévèrement hypoxiques se sont développées depuis les derniers 80 ans. Nous avons reconstitué l'évolution du pH des eaux de fond à l'aide de mesures historiques et récentes ainsi que des principes de base qui décrivent la relation stoéchiométrique entre la consommation d'oxygène et la production de CO 2 métabolique issu de la dégradation microbienne de la matière organique. Selon la valeur de la pression partielle en CO 2 qui reproduit le plus précisément les concentrations de carbone inorganique dissous préformées dans les eaux profondes, nous avons estimé l'âge moyen de ces eaux à 16 ± 3 ans. Le pH des eaux profondes s'est abaissé de 0.2 à 0.3 depuis 75 ans, ce qui est de 4 à 6 fois plus important que ce qui est attribuable au transfert du CO 2 anthropique. La décroissance du pH est accompagnée par une diminution du degré de saturation par rapport à la calcite et l'aragonite. En 2007, les eaux profondes de l'EMSL demeurent légèrement sursaturées par rapport à la calcite (Ω c ≈ 1.06 ± 0.04) mais sont sévèrement sous-saturées par rapport à l'aragonite (Ω a ≈ 0.67 ± 0.03).

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Temporal responses of coastal hypoxia to nutrient loading and physical controls

Cited by 363 publications

References 169 publications

Natural and human-induced hypoxia and consequences for coastal areas: synthesis and future development

Natural and human-induced hypoxia and consequences for coastal areas: synthesis and future development

Hydrological and biological processes modulate carbon, nitrogen and phosphorus flux from the St. Lawrence River to its estuary (Quebec, Canada)

Acidification of Lower St. Lawrence Estuary Bottom Waters

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