Abstract
Abstract. The Texas-Louisiana shelf in the Northern Gulf of Mexico receives large inputs of nutrients and freshwater from the Mississippi/Atchafalaya River system. The nutrients stimulate high rates of primary production in the river plume, which contributes to the development of a large and recurring hypoxic area in summer, but the mechanistic links between hypoxia and river discharge of freshwater and nutrients are complex as the accumulation and vertical export of organic matter, the establishment and maintenance of vertical stratification, and the microbial degradation of organic matter are controlled by a non-linear interplay of factors. Unraveling these interactions will have to rely on a combination of observations and models. Here we present results from a realistic, 3-dimensional, physical-biological model with focus on a quantification of nutrient-stimulated phytoplankton growth, its variability and the fate of this organic matter. We demonstrate that the model realistically reproduces many features of observed nitrate and phytoplankton dynamics including observed property distributions and rates. We then contrast the environmental factors and phytoplankton source and sink terms characteristic of three model subregions that represent an ecological gradient from eutrophic to oligotrophic conditions. We analyze specifically the reasons behind the counterintuitive observation that primary production in the light-limited plume region near the Mississippi River delta is positively correlated with river nutrient input, and find that, while primary production and phytoplankton biomass are positively correlated with nutrient load, phytoplankton growth rate is not. This suggests that accumulation of biomass in this region is not primarily controlled bottom up by nutrient-stimulation, but top down by systematic differences in the loss processes.
Highlights
The Texas-Louisiana shelf in the Northern Gulf of Mexico is dominated by large seasonal inputs of freshwater and inorganic and organic nutrients from the Mississippi/Atchafalaya River system
We investigate the question why primary production rates in the plume region are correlated with nitrogen concentrations and river nitrate loads, even though primary production is light-limited in this region and, should not be sensitive to variations in nutrient concentrations and nutrient load
We examine relationships between monthly mean primary production in the delta region and Mississippi River nitrate load in order to elucidate why primary production in this region is correlated with nitrate load even though phytoplankton growth is not limited by nitrate
Summary
The Texas-Louisiana shelf in the Northern Gulf of Mexico is dominated by large seasonal inputs of freshwater and inorganic and organic nutrients from the Mississippi/Atchafalaya River system. The Mississippi River drains 41 % of the contiguous USA, including agricultural land in Southern Minnesota, Iowa, Illinois and Ohio, which contributes about one third of the nitrogen loading of the river (Goolsby et al, 2000). The mean annual nitrogen load to the Gulf of Mexico of 1.5 Mt yr−1 consists of approximately 61 % nitrate, 37 % organic nitrogen and 2 % ammonium (1980–1996 mean), and the nitrate load has approximately tripled from 1970 to the late 90ies (Goolsby et al, 2000). The large nutrient input from the Mississippi River stimulates phytoplankton growth, which contributes to the development of a large recurring hypoxic area on the TexasLouisiana shelf in summer (Rabalais et al, 2002).
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