T M Quan1, P G Falkowski. 1. Institute of Marine and Coastal Sciences, Rutgers University, New Brunswick, NJ 08901, USA. quan@marine.rutgers.edu
Abstract
The ratio of dissolved fixed inorganic nitrogen to soluble inorganic phosphate (N:P) in the ocean interior is relatively constant, averaging approximately 16 : 1 by atoms. In contrast, the ratio of these two elements spans more than six orders of magnitude in lakes and other aquatic environments. To understand the factors influencing N:P ratios in aquatic environments, we analyzed 111 observational datasets derived from 35 water bodies, ranging from small lakes to ocean basins. Our results reveal that N:P ratios are highly correlated with the concentration of dissolved O(2) below approximately 100 micromol L(-1). At higher concentrations of O(2), N:P ratios are highly variable and not correlated with O(2); however, the coefficient of variation in N:P ratios is strongly related to the size of the water body. Hence, classical Redfield ratios observed in the ocean are anomalous; this specific elemental stoichiometry emerges not only as a consequence of the elemental ratio of the sinking flux of organic matter, but also as a result of the size of the basins and their ventilation. We propose that the link between N:P ratios, basin size and oxygen levels, along with the previously determined relationship between sedimentary delta(15)N and oxygen, can be used to infer historical N:P ratios for any water body.
The ratio of dissolved fixed inorganic nitrogen to soluble n>an class="Chemical">inorganic phosphate (N:P) in the ocean interior is relatively constant, averaging approximately 16 : 1 by atoms. In contrast, the ratio of these two elements spans more than six orders of magnitude in lakes and other aquatic environments. To understand the factors influencing N:P ratios in aquatic environments, we analyzed 111 observational datasets derived from 35 water bodies, ranging from small lakes to ocean basins. Our results reveal that N:P ratios are highly correlated with the concentration of dissolved O(2) below approximately 100 micromol L(-1). At higher concentrations of O(2), N:P ratios are highly variable and not correlated with O(2); however, the coefficient of variation in N:P ratios is strongly related to the size of the water body. Hence, classical Redfield ratios observed in the ocean are anomalous; this specific elemental stoichiometry emerges not only as a consequence of the elemental ratio of the sinking flux of organic matter, but also as a result of the size of the basins and their ventilation. We propose that the link between N:P ratios, basin size and oxygen levels, along with the previously determined relationship between sedimentary delta(15)N and oxygen, can be used to infer historical N:P ratios for any water body.
Authors: Kathleen Trautwein; Christoph Feenders; Reiner Hulsch; Hanna S Ruppersberg; Annemieke Strijkstra; Mirjam Kant; Jannes Vagts; Daniel Wünsch; Bernhard Michalke; Michael Maczka; Stefan Schulz; Helmut Hillebrand; Bernd Blasius; Ralf Rabus Journal: FEMS Microbiol Ecol Date: 2017-05-01 Impact factor: 4.194