Reduced nitrogen fixation in the glacial ocean inferred from changes in marine nitrogen and phosphorus inventories

To explain the lower atmospheric CO2 concentrations during glacial periods, it has been suggested that the productivity of marine phytoplankton was stimulated by an increased flux of iron-bearing dust to the oceans. One component of this theory is that iron-an essential element/nutrient for nitrogen...

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Published in	Nature (London) Vol. 415; no. 6868; pp. 156 - 159
Main Authors	Ganeshram, Raja S, Pedersen, Thomas F, Calvert, Stephen, François, Roger
Format	Journal Article
Language	English
Published	London Nature Publishing 10.01.2002 Nature Publishing Group
Subjects	Atmosphere Carbon Dioxide - metabolism Cold Climate Earth sciences Earth, ocean, space Exact sciences and technology Geologic Sediments Marine Marine and continental quaternary Marine geology Minerals - metabolism Models, Biological Nitrogen - metabolism Nitrogen Fixation Oceans and Seas Phosphates - metabolism Phosphorus - metabolism Phytoplankton - metabolism Seawater Surficial geology Time Mexico Pacific Ocean ISE, Mexico ISE, East Pacific atmosphere carbon dioxide nitrogen drilling North America chemically precipitated rocks denitrification remobilization nutrients sedimentary rocks drill cores chemical ratios ocean productivity upwelling phosphate rocks fixation phytoplankton iron plankton continental margin glacial periods marine sediments phosphorus
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Abstract	To explain the lower atmospheric CO2 concentrations during glacial periods, it has been suggested that the productivity of marine phytoplankton was stimulated by an increased flux of iron-bearing dust to the oceans. One component of this theory is that iron-an essential element/nutrient for nitrogen-fixing organisms-will increase the rate of marine nitrogen fixation, fuelling the growth of other marine phytoplankton and increasing CO2 uptake. Here we present data that questions this hypothesis. From a sediment core off the northwestern continental margin of Mexico, we show that denitrification and phosphorite formation-processes that occur in oxygen-deficient upwelling regions, removing respectively nitrogen and phosphorus from the ocean-declined in glacial periods, thus increasing marine inventories of nitrogen and phosphorus. But increases in phosphorus were smaller and less rapid, leading to increased N/P ratios in the oceans. Acknowledging that phytoplankton require nitrogen and phosphorus in constant proportions, the Redfield ratio, and that N/P ratios greater than the Redfield ratio are likely to suppress nitrogen fixation, we suggest therefore that marine productivity did not increase in glacial periods in response to either increased nutrient inventories or greater iron supply.
AbstractList	To explain the lower atmospheric CO2 concentrations during glacial periods, it has been suggested that the productivity of marine phytoplankton was stimulated by an increased flux of iron-bearing dust to the oceans. One component of this theory is that iron, an essential element/nutrient for nitrogen-fixing organisms, will increase the rate of marine nitrogen fixation, fueling the growth of other marine phytoplankton and increasing CO2 uptake. Here, we present data that questions this hypothesis. From a sediment core off the northwestern continental margin of Mexico, we show that denitrification and phosphorite formation, processes that occur in oxygen-deficient upwelling regions, removing respectively nitrogen and phosphorus from the ocean, declined in glacial periods, thus increasing marine inventories of nitrogen and phosphorus. But increases in phosphorus were smaller and less rapid, leading to increased N/P ratios in the oceans. Acknowledging that phytoplankton require nitrogen and phosphorus in constant proportions, the Redfield ratio (Redfield et al., 1963), and that N/P ratios greater than the Redfield ratio are likely to suppress nitrogen fixation, we suggest, therefore, that marine productivity did not increase in glacial periods in response to either increased nutrient inventories or greater iron supply. (Author) Experts seeking to explain the lower concentrations of atmospheric carbon dioxide associated with periods of glaciation have indicated that the productivity of marine phytoplankton was boosted by an increased flux of iron-bearing dust to the world's oceans. Iron is an essential nutrient for nitrogen-fixing organisms. Findings are reported from a study enacted to question these theories. Data from a sediment core collected from off the northwestern continental margin of Mexico indicated that denitrification and phosphorite formation were reduced during periods of glaciation. This process would lead to increases in marine inventories of nitrogen and phosphorus. These changes led to excessive N/P ratios in the oceans, resulting in reduced N fixation. To explain the lower atmospheric CO2 concentrations during glacial periods, it has been suggested that the productivity of marine phytoplankton was stimulated by an increased flux of iron-bearing dust to the oceans. One component of this theory is that iron-an essential element/nutrient for nitrogen-fixing organisms-will increase the rate of marine nitrogen fixation, fuelling the growth of other marine phytoplankton and increasing CO2 uptake. Here we present data that questions this hypothesis. From a sediment core off the northwestern continental margin of Mexico, we show that denitrification and phosphorite formation-processes that occur in oxygen-deficient upwelling regions, removing respectively nitrogen and phosphorus from the ocean-declined in glacial periods, thus increasing marine inventories of nitrogen and phosphorus. But increases in phosphorus were smaller and less rapid, leading to increased N/P ratios in the oceans. Acknowledging that phytoplankton require nitrogen and phosphorus in constant proportions, the Redfield ratio, and that N/P ratios greater than the Redfield ratio are likely to suppress nitrogen fixation, we suggest therefore that marine productivity did not increase in glacial periods in response to either increased nutrient inventories or greater iron supply. To explain the lower atmospheric CO sub(2) concentrations during glacial periods, it has been suggested that the productivity of marine phytoplankton was stimulated by an increased flux of iron-bearing dust to the oceans. One component of this theory is that iron--an essential element/nutrient for nitrogen-fixing organisms--will increase the rate of marine nitrogen fixation, fuelling the growth of other marine phytoplankton and increasing CO sub(2) uptake. Here we present data that questions this hypothesis. From a sediment core off the northwestern continental margin of Mexico, we show that denitrification and phosphorite formation--processes that occur in oxygen-deficient upwelling regions, removing respectively nitrogen and phosphorus from the ocean--declined in glacial periods, thus increasing marine inventories of nitrogen and phosphorus. But increases in phosphorus were smaller and less rapid, leading to increased N/P ratios in the oceans. Acknowledging that phytoplankton require nitrogen and phosphorus in constant proportions, the Redfield ratio, and that N/P ratios greater than the Redfield ratio are likely to suppress nitrogen fixation, we suggest therefore that marine productivity did not increase in glacial periods in response to either increased nutrient inventories or greater iron supply.
Audience	Academic
Author	François, Roger Ganeshram, Raja S Calvert, Stephen Pedersen, Thomas F
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Keywords	atmosphere carbon dioxide nitrogen drilling North America chemically precipitated rocks denitrification remobilization nutrients sedimentary rocks drill cores chemical ratios ocean productivity upwelling phosphate rocks fixation phytoplankton iron plankton continental margin glacial periods marine sediments phosphorus
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Snippet	To explain the lower atmospheric CO2 concentrations during glacial periods, it has been suggested that the productivity of marine phytoplankton was stimulated... Experts seeking to explain the lower concentrations of atmospheric carbon dioxide associated with periods of glaciation have indicated that the productivity of... To explain the lower atmospheric CO sub(2) concentrations during glacial periods, it has been suggested that the productivity of marine phytoplankton was...
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SubjectTerms	Atmosphere Carbon Dioxide - metabolism Cold Climate Earth sciences Earth, ocean, space Exact sciences and technology Geologic Sediments Marine Marine and continental quaternary Marine geology Minerals - metabolism Models, Biological Nitrogen - metabolism Nitrogen Fixation Oceans and Seas Phosphates - metabolism Phosphorus - metabolism Phytoplankton - metabolism Seawater Surficial geology Time
Title	Reduced nitrogen fixation in the glacial ocean inferred from changes in marine nitrogen and phosphorus inventories
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