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Estuaries and Nutrients pp 111–138Cite as

Remineralization and Nutrient Cycling in Coastal Marine Ecosystems

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Part of the book series: Contemporary Issues in Science and Society ((CISS))

Abstract

Our views of remineralization and nutrient cycling in coastal marine ecosystems have changed considerably over the last 30 years. The major trend has been an increasing appreciation for the complexity of processes involved, including some marked changes in our assessment of the importance of bacteria with respect to smaller animals and in our perception of the association between bacteria and particulate matter in the sea. Among the more recent developments in this area is a growing awareness of the importance of the coupling between benthic and pelagic communities in coastal waters. There appears to be a strong linear correlation between the organic matter produced in the overlying water and the amount of organic matter consumed on the bottom in almost all of the coastal environments for which annual data are available. The large amount of organic matter consumed by the benthos (perhaps 25–50 percent of that produced) is associated with a large flux of inorganic nutrients from the sediments to the overlying water. The stoichiometry of net benthic nutrient regeneration differs from that of pelagic regeneration, however, and simple Redfield type models probably cannot be applied. The amount of fixed inorganic nitrogen returned to the water across the sediment-water interface appears to be about half of that expected on the basis of the flux of phosphorus. This behavior, along with the fact that an appreciable amount of organic matter in coastal waters gets remineralized on the bottom, contributes to the low N/P ratio that is characteristic of these areas and may be responsible for the observation that nitrogen is commonly the nutrient most limiting for primary production. Recent direct measurements of the flux of dissolved N2 across the sediment-water interface indicate that denitrification is probably responsible for the loss of fixed nitrogen during decomposition in the sediments. If this is a widespread phenomenon, estuaries, bays, and other coastal waters may be major sinks in the marine nitrogen cycle and important terms in the global nitrogen budget. However, the fact that eutrophication appears to be an increasing problem in many estuaries is dramatic warning that anthropogenic nutrient inputs can overwhelm the recycling and remineralization processes in coastal waters.

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  1. Graduate School of Oceanography, University of Rhode Island, Kingston, Rhode Island, 02881, USA

    Scott W. Nixon

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  1. Virginia Institute of Marine Science, USA

    Bruce J. Neilson

  2. Chesapeake Research Consortium, USA

    Lewis Eugene Cronin

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Nixon, S.W. (1981). Remineralization and Nutrient Cycling in Coastal Marine Ecosystems. In: Neilson, B.J., Cronin, L.E. (eds) Estuaries and Nutrients. Contemporary Issues in Science and Society. Humana Press. https://doi.org/10.1007/978-1-4612-5826-1_6

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