one publication added to basket [23709] | Dissolved inorganic carbon in a highly polluted estuary (the Scheldt)
Hellings, L.; Dehairs, F.; Van Damme, S.; Baeyens, W. (2001). Dissolved inorganic carbon in a highly polluted estuary (the Scheldt). Limnol. Oceanogr. 46(6): 1406-1414. dx.doi.org/10.4319/lo.2001.46.6.1406 In: Limnology and Oceanography. American Society of Limnology and Oceanography: Waco, Tex., etc. ISSN 0024-3590; e-ISSN 1939-5590, more | |
Keywords | Characteristics > Origin Fluxes Isotope fractionation Model Physics > Mechanics > Dynamics Welding fluxes > Fluxes ANE, Belgium [Marine Regions]; ANE, Netherlands [Marine Regions]; Belgium [Marine Regions] Marine/Coastal; Brackish water |
Abstract | During 34 months (1996-1999), we studied the dissolved inorganic carbon (DIC) system of the highly polluted Scheldt River and upper estuary. DIC ranged between 3,300 and 7,100 µM, with highest values in winter and lowest in summer. For the brackish and freshwater section of the river d 13CDIC values ranged from -7.5 to -17.5 parts per thousand, the most negative signals were during winter and the least negative during summer. In all seasons, surface waters were significantly supersaturated in CO2 with respect to the atmosphere (pCO2) ranged from 2,200 to a maximum of 15,500 µatm) indicating that the system is always heterotrophic. Biological processes (respiration and carbon fixation) and CO2 evasion to the atmosphere affected the isotopic composition and magnitude of the inorganic carbon pool. In spring and summer 1997 and 1998, large phytoplankton biomasses (> 100 µg chlorophyll a [Chl a] L-1) coincided with lower pCO2) and CO2 water-air efflux and less negative d 13CDIC values, indicating considerable CO2 drawdown by phytoplankton. Mass balance calculations indicated that organic carbon to DIC conversion exceeded CO2 consumption year round, (net organic carbon conversion ranged from 410 to 520 a C m-2 yr-1) emphasizing the effect of bacterial respiration. An intermediate river section receiving water from the main tributary (Rupel), which carries wastewater from the densely populated Brussels region, consistently showed decreased DIC, increased pCO2), and depletion in 13CDIC relative to the main river system. |
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