Phosphorus accumulation in marine sediments and the oceanic phosphorus cycle
Reads0
Chats0
TLDR
In this paper, the authors present an integrated overview of key factors in the oceanic mass balance of dissolved, reactive phosphate, with an emphasis on evaluating the burial sinks for P and defining areas needing further research.Abstract:
Ideas about key factors in the oceanic mass balance of dissolved, reactive phosphate have changed substantially. I present an integrated overview of these here, with an emphasis on evaluating the burial sinks for P and defining areas needing further research. The major source of reactive P to the ocean is river input. Reactive P is delivered to the oceanic sediment-water interface primarily in particulate organic matter. P scavenged by hydrothermal iron-rich oxyhydroxide particles, with uptake in proportion to deep water phosphate concentrations, represents a substantially smaller flux to the sediment-water interface. Diagenetic transformations are important influences on the form of reactive P burial in marine sediments. P burial occurs with organic carbon burial and as P associated with iron-rich oxyhydroxide particles and coatings. Formation of authigenic P-rich phases, presumably apatite, at the expense of organic P and oxide-associated P, is significant in open ocean marine sediments. The authigenic P sink may represent a substantially larger portion of the sedimentary burial than indicated by previous estimates focused on P burial in organic-rich continental margin sediments.read more
Citations
More filters
Journal ArticleDOI
The biogeochemical cycling of phosphorus in marine systems
TL;DR: In this paper, a comprehensive review of the biogeochemical cycling of P within the oceans is given, with particular attention focused on the composition and recycling rates of P in the water column.
Journal ArticleDOI
The oceanic phosphorus cycle.
Adina Paytan,Karen McLaughlin +1 more
TL;DR: Research in the Pacific Ocean gyres indicates that biological P uptake rates far surpass the combined input from atmospheric and deep water sources, suggesting that P is efficiently recycled within oligotrophic euphotic zones.
Journal ArticleDOI
The World Ocean Silica Cycle
TL;DR: The resulting budget recognizes significantly higher input and output fluxes and notes that the recycling of silicon occurs mostly at the sediment-water interface and not during the sinking of silica particles through deep waters.
Journal ArticleDOI
Evolution of the global phosphorus cycle
Christopher T. Reinhard,Noah J. Planavsky,Benjamin C. Gill,Kazumi Ozaki,Kazumi Ozaki,Leslie J. Robbins,Timothy W. Lyons,Woodward W. Fischer,Chunjiang Wang,Devon B. Cole,Kurt O. Konhauser +10 more
TL;DR: A compilation of phosphorus abundances in marine sedimentary rocks spanning the past 3.5 billion years is presented and it is found that a combination of enhanced phosphorus scavenging in anoxic, iron-rich oceans and a nutrient-based bistability in atmospheric oxygen levels could have resulted in a stable low-oxygen world.
Journal ArticleDOI
Total organic carbon, organic phosphorus, and biogenic barium fluxes as proxies for paleomarine productivity
Shane D. Schoepfer,Jun Shen,Jun Shen,Hengye Wei,R. V. Tyson,Ellery D. Ingall,Thomas J. Algeo,Thomas J. Algeo +7 more
TL;DR: In this paper, the accumulation rates of three commonly used proxies for productivity from a set of primarily Quaternary sediment cores at 94 marine sites, compiled from 37 published sources, were evaluated for total organic carbon, organic phosphorus, and biogenic barium (Babio).
References
More filters
Journal ArticleDOI
Geocarb III: A Revised Model of Atmospheric CO2 over Phanerozoic Time
TL;DR: In this article, the GEOCARB model has been updated with an emphasis on factors affecting CO2 uptake by continental weathering, including the role of plants in chemical weathering and the application of GCMs to study the long-term carbon cycle.
Journal ArticleDOI
The atmospheric input of trace species to the world ocean
Robert A. Duce,Peter S. Liss,John T. Merrill,Elliot Atlas,Patrick Buat-Ménard,B. B. Hicks,John M. Miller,Joseph M. Prospero,Richard Arimoto,Thomas M. Church,W. G. Ellis,James N. Galloway,LeRoy Hansen,Tim Jickells,Anthony H. Knap,K. H. Reinhardt,B. Schneider,A. Soudine,J. J. Tokos,S. Tsunogai,R. Wollast,M. Y. Zhou +21 more
TL;DR: In this paper, the authors assess current data in this area, develop global scale estimates of the atmospheric fluxes of trace elements, mineral aerosol, nitrogen species, and synthetic organic compounds to the ocean; and compare the atmospheric input rates of these substances to their input via rivers.
Journal ArticleDOI
Production and dissolution of biogenic silica in the ocean: Revised global estimates, comparison with regional data and relationship to biogenic sedimentation
TL;DR: In this article, the global rate of biogenic silica production in the ocean was estimated to be between 200 and 280 × 1012 mol Si yr−1, which is 30-50% lower than several previous estimates, due to new data indicating lower values for both the relative contribution of diatoms to primary productivity and their Si/C ratios.