Gross primary production and nutrient behaviour in a shallow coastal environment
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2020, Journal of HydrologyCitation Excerpt :Excess nitrate generated from non-point sources (e.g., fertilizer from agricultural lands) and point sources (e.g., septic tanks in urban areas) may exceed the denitrification capacity in topsoil and allow nitrate to leach into groundwater systems thus causing nitrate pollution in Florida’s groundwater and surface water systems (Castro et al., 2018; Ritter et al., 2007; Shamrukh et al., 2001). Elevated nitrate-N concentrations in drinking water can cause serious health problems, specifically to infants (e.g., methemoglobinemia) and excess concentrations of dissolved nitrate in surface water will lead to eutrophication and may increase the gross primary production of water bodies (Coinly, 1945; Gardner and Vogel, 2005; Sfriso and Marcomini, 1994). The National Drinking Water Regulations have the maximum contaminant level for nitrate in drinking water set to 10 mg/L, measured as nitrate-nitrogen (NO3-N).
Is coastal lagoon eutrophication likely to be aggravated by global climate change?
2008, Estuarine, Coastal and Shelf ScienceCitation Excerpt :Grall and Chauvaud (2002) stated that in some ecosystems benthic macrophytes may store nutrients in the same order of magnitude as the annual nutrient load coming from freshwater inputs. Other authors demonstrated that the total nutrient amounts stored by macroalgal biomass can be even higher (Sfriso and Marcomini, 1994; Sfriso et al., 1994). This is particularly true in the Mar Menor lagoon where annual inputs from the main watercourse flowing into the lagoon from the adjacent agricultural area have been estimated at 2010 tonnes N yr−1 and 178 tonnes P yr−1 (Velasco et al., 2006); these values are half of our estimation of algae uptake of 3988 tonnes N yr−1 and 420 tonnes P yr−1.
Recording the occurrence of trophic level changes in the lagoon of Venice over the '90s
2005, Environment InternationalTemporal and spatial changes of macroalgae and phytoplankton in a Mediterranean coastal area: The Venice lagoon as a case study
2003, Marine Environmental ResearchDistribution of heavy metals in sediments of the Venice Lagoon: The role of the industrial area
2002, Science of the Total EnvironmentHeavy metal contamination in the seaweeds of the Venice lagoon
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