The stoichiometry of inorganic carbon and nutrient removal in the Mississippi River plume and adjacent continental shelf

Huang, Wei‐Jen; Cai, Wei‐Jun; Powell, Rodney T.; Lohrenz, Steven E.; Wang, Y.; Jiang, Li‐Qing; Hopkinson, Charles S.

doi:10.5194/bg-9-2781-2012

Cited by 34 publications

(47 citation statements)

References 53 publications

(73 reference statements)

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“…7.6), whereas such overall removal is apparent in the Mississippi plume (Fig. 7.5) (Cai 2003;Guo et al 2012;Huang et al 2012), in the Pearl River plume (Cai et al 2004;Dai et al 2008), and the Changjiang plume (Wang et al 2000;Chou et al 2009b).…”

Section: Co 2 In the Amazon River Plumementioning

confidence: 94%

“…Other factors also matter. For example, the Mississippi River has lower turbidity than the Changjiang River, and thus high biological production and CO 2 removal in the plume has occurred at low salinity zone of 20 to 30 or occasionally even at salinity as low as 12 (Dagg et al 2008;Huang et al 2012) in the Mississippi plume, whereas in the Changjiang plume, biological bloom rarely has occurred at salinity less than 28. Figure 7.6.…”

Section: Co 2 In the Mississippi River Plumementioning

confidence: 99%

“…Regarding carbonate system distribution and dynamics, the northern Gulf of Mexico shelf appears as a three end-member mixing system except during the extremely low discharge time (later summer) when the Atchafalaya River has essentially Mississippi River water (Cai 2003;Guo et al 2012;Huang et al 2012). In addition, river end-member values can change with time rapidly.…”

Section: Co 2 In the Mississippi River Plumementioning

confidence: 99%

See 2 more Smart Citations

Carbon dioxide dynamics and fluxes in coastal waters influenced by river plumes

Cai

Chen²,

Borges³

2013

Biogeochemical Dynamics at Major River-Coastal Interfaces

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Section: Co 2 In the Amazon River Plumementioning

confidence: 94%

Section: Co 2 In the Mississippi River Plumementioning

confidence: 99%

Section: Co 2 In the Mississippi River Plumementioning

confidence: 99%

See 1 more Smart Citation

Carbon dioxide dynamics and fluxes in coastal waters influenced by river plumes

Cai

Chen²,

Borges³

2013

Biogeochemical Dynamics at Major River-Coastal Interfaces

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“…We also took advantage of extensive in situ observations (shipboard CTD casts and Niskin bottle samplings) collected during research cruises in the northern GoM spanning over the period of 2005-2010 (Data were collected from different sources, including the Environmental Protection Agency; Lehrter et al, 2009Lehrter et al, , 2012Lohrenz et al, 2008;Cai et al, 2011;Huang et al, 2012; Louisiana Universities Marine Consortium; Rabalais et al, 2007; Mechanisms Controlling Hypoxia (MCH) Project; Southeast Monitoring and Assessment Program (SEAMAP); the NSF-funded GulfCarbon Project and Mississippi-Atchafalaya-Gulf of Mexico Mixing Experiment (MMAGMIX)). Together, there are more than 8000 surface observations of water temperature, salin- ity, NO 3 , NH 4 , and chlorophyll concentrations.…”

Section: Model-data Comparisonsmentioning

confidence: 99%

Modeling ocean circulation and biogeochemical variability in the Gulf of Mexico

Xue

Fennel

et al. 2013

Biogeosciences

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Abstract.A three-dimensional coupled physicalbiogeochemical model is applied to simulate and examine temporal and spatial variability of circulation and biogeochemical cycling in the Gulf of Mexico (GoM). The model is driven by realistic atmospheric forcing, open boundary conditions from a data assimilative global ocean circulation model, and observed freshwater and terrestrial nitrogen input from major rivers. A 7 yr model hindcast (2004)(2005)(2006)(2007)(2008)(2009)(2010) was performed, and validated against satellite observed sea surface height, surface chlorophyll, and in situ observations including coastal sea level, ocean temperature, salinity, and dissolved inorganic nitrogen (DIN) concentration. The model hindcast revealed clear seasonality in DIN, phytoplankton and zooplankton distributions in the GoM. An empirical orthogonal function analysis indicated a phaselocked pattern among DIN, phytoplankton and zooplankton concentrations. The GoM shelf nitrogen budget was also quantified, revealing that on an annual basis the DIN input is largely balanced by the removal through denitrification (an equivalent of ∼ 80 % of DIN input) and offshore exports to the deep ocean (an equivalent of ∼ 17 % of DIN input).

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“…Within the Mississippi River plume, Cai (2003) observed that DIC losses occurred where salinity was , 30 and noted the cause might be a combination of biological production and CaCO 3 precipitation. Guo et al (2012) and Huang et al (2012) subsequently concluded that biological production was the main cause for the plume DIC removal and the effect of CaCO 3 precipitation was minor.…”

mentioning

confidence: 99%

Removal of dissolved inorganic carbon in the Yellow River Estuary

Liu

Zhang

Cai

et al. 2014

Limnology & Oceanography

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The Yellow River of China runs mainly through an arid and semiarid midlatitude region that has experienced substantial anthropogenic and climatic change. This area includes the carbonate-rich Loess Plateau and carries water of exceptionally high carbonate content. To investigate the processes by which dissolved inorganic carbon (DIC) is biogeochemically modified as the river approaches the sea, a multipronged field investigation was conducted in the Yellow River estuary, [2005][2006][2007][2008][2009]. The project included four research cruises (spring and fall), a year of monthly sampling at a lower-river hydrological station (Lijin), and in situ bottle incubations. Our study revealed that 4-11% of the Yellow River DIC was removed from the water column in the estuarine mixing zone and thus was not transported to the sea. DIC removal was greater in the spring and occurred at a higher salinity range than in the fall. As a unique feature of the Yellow River estuary, calcium carbonate (CaCO 3 ) precipitation was nearly as important as net biological production in the DIC removal. Longer freshwater-seawater mixing distances (and times) and higher DIC concentrations in the freshwater end member also promoted net biological production and CaCO 3 precipitation, thus encouraging DIC removal.

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The stoichiometry of inorganic carbon and nutrient removal in the Mississippi River plume and adjacent continental shelf

Cited by 34 publications

References 53 publications

Carbon dioxide dynamics and fluxes in coastal waters influenced by river plumes

Carbon dioxide dynamics and fluxes in coastal waters influenced by river plumes

Modeling ocean circulation and biogeochemical variability in the Gulf of Mexico

Removal of dissolved inorganic carbon in the Yellow River Estuary

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