Phosphorus burial as a function of paleoproductivity and redox conditions in Arabian Sea sediments
Publication date
2005
Authors
Schenau, S.J.
Reichart, G.-J.
Lange, G.J. de
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Document Type
Article
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(c) UU Universiteit Utrecht, 2005
Abstract
Abstract—In this study the response of sedimentary phosphorus (P) burial to changes in primary productivity
and bottom water oxygen concentrations during the Late Quaternary is investigated, using two sediment cores
from the Arabian Sea, one recovered from the continental slope and the other from the deep basin. The average
solid-phase P speciation in both cores is similar, authigenic and biogenic (fish debris) apatite make up the bulk
of the P inventory (ca. 70%);whereas P adsorbed to iron oxides, organic P, and detrital apatite constitute minor
fractions. Postdepositional redistribution has not significantly altered the downcore distribution of total
solid-phase P. Phosphorus burial efficiencies are generally lower during periods of increased paleoproductivity.
This is caused by (a) partial decoupling of the P export flux, consisting primarily of particulate organic
P, and the P burial flux, consisting primarily of biogenic and authigenic apatite; and (b) the lack of increased
rates of authigenic CFA formation during periods of higher P deposition. In addition, fluctuations in bottom
water oxygen concentrations may have affected P burial in continental slope sediments. The results of this
study indicate that higher primary productivity induces more efficient P cycling. On time scales exceeding the
oceanic P residence time, this process may induce higher surface water productivity, thus creating a positive
feedback loop. In the Arabian Sea, this feedback mechanism may have contributed to changes in sea surface
productivity on sub-Milankovitch time scales because P, regenerated on the continental slopes of the Oman
and Somalian coastal upwelling zones, is reintroduced into the photic zone relatively fast.