Phosphorus diagenesis in deep-sea sediments: Sensitivity to water column conditions and global scale implications

Abstract The geological record bears evidence of various periods of wide-scale oceanic anoxia that are associated with perturbations of the marine carbon and phosphorus (P) cycles. In this study, we examine the impact of changes in bottom water oxygen and organic matter (OM) input on burial of P in deep-sea sediments using a reactive-transport model. Results show that the burial of key reactive P phases, namely authigenic calcium associated P minerals (Ca–P), organic P (org P) and iron-bound P (Fe–P), responds non-linearly to both water column forcings, namely water column oxygenation and OM loading. High organic matter (OM) flux with either very low or high oxygen (~ 180 μM) favor the formation of authigenic Ca–P, while low oxygen and intermediate to high OM fluxes promote org P burial. Iron-bound P is only preserved in the sediment when oxygen levels are high and OM fluxes low. The conditions for maximum P recycling (or minimum P burial) are low bottom water oxygen concentrations and low OM fluxes to the sediment–water interface (hypoxic, oligotrophic deep-sea settings). The bivariate dependence of P burial on oxygen and OM flux was implemented in an existing box model of the global marine P, oxygen and organic carbon cycles, replacing simple empirical redox functions for P burial. The response of the original and new box model to decreased ocean mixing was then assessed, in the context of a long-term response. In the new model, org P instead of authigenic Ca–P is the dominant burial phase of P in deep-sea environments during periods of oceanic anoxia. Nevertheless, reduced ocean mixing leads to a similar response in total P burial and, as a consequence, to a similar increase in deep water anoxia and decrease in open ocean productivity whether an empirical or mechanistic description of phosphorus diagenesis is considered.

[1]  R. Bustin,et al.  Influence of water column anoxia on the burial and preservation of carbon and phosphorus in marine shales , 1993 .

[2]  Robert A. Berner,et al.  An idealized model of dissolved sulfate distribution in recent sediments , 1964 .

[3]  H. Jenkyns Geochemistry of oceanic anoxic events , 2010 .

[4]  M. Kuypers,et al.  Phosphorus cycling from the margin to abyssal depths in the proto-Atlantic during oceanic anoxic event 2 , 2010 .

[5]  C. Slomp,et al.  Shelf erosion and submarine river canyons: implications for deep-sea oxygenation and ocean productivity during glaciation , 2010 .

[6]  R. Jahnke,et al.  Rates of formation of modern phosphorite off western Mexico , 1994 .

[7]  C. Slomp,et al.  The global marine phosphorus cycle: sensitivity to oceanic circulation , 2006 .

[8]  B. Gustafsson,et al.  Phosphorus recycling and burial in Baltic Sea sediments with contrasting redox conditions , 2010 .

[9]  Robert M. Key,et al.  A global model for the early diagenesis of organic carbon and organic phosphorus in marine sediments , 1995 .

[10]  W. Martin,et al.  Benthic organic carbon degradation and biogenic silica dissolution in the central equatorial Pacific , 1991 .

[11]  C. Slomp,et al.  The role of adsorption in sediment‐water exchange of phosphate in North Sea continental margin sediments , 1998 .

[12]  Leonard R. Pasion,et al.  Quantitative interpretation of pore water O2 and pH distributions in deep-sea sediments , 2008 .

[13]  W. Berelson,et al.  The Flux of Particulate Organic Carbon Into the Ocean Interior: A Comparison of Four U.S. JGOFS Regional Studies , 2001 .

[14]  Bernard P. Boudreau,et al.  A method-of-lines code for carbon and nutrient diagenesis in aquatic sediments , 1996 .

[15]  P. Müller,et al.  Productivity, sedimentation rate, and sedimentary organic matter in the oceans—I. Organic carbon preservation , 1979 .

[16]  M. Kuypers,et al.  Pyrite oxidation during sample storage determines phosphorus fractionation in carbonate-poor anoxic sediments , 2009 .

[17]  C. Slomp,et al.  Enhanced regeneration of phosphorus during formation of the most recent eastern Mediterranean sapropel (S1) , 2002 .

[18]  George Veronis,et al.  On weighted-mean schemes for the finite-difference approximation to the advection-diffusion equation , 1977 .

[19]  Karline Soetaert,et al.  Oxygenation and organic-matter preservation in marine sediments: Direct experimental evidence from ancient organic carbon–rich deposits , 2005 .

[20]  J. Allen,et al.  Oxygen in Pore Waters of Deep-Sea Sediments [and Discussion] , 1990 .

[21]  C. Heinze,et al.  Long‐term controls on ocean phosphorus and oxygen in a global biogeochemical model , 2011 .

[22]  C. Slomp,et al.  Controls on phosphorus regeneration and burial during formation of eastern Mediterranean sapropels , 2004 .

[23]  Andrew W. Dale,et al.  Global‐scale quantification of mineralization pathways in marine sediments: A reaction‐transport modeling approach , 2009 .

[24]  S. Schenau,et al.  Phosphorus regeneration vs. burial in sediments of the Arabian Sea , 2001 .

[25]  Karline Soetaert,et al.  Inverse Modelling, Sensitivity and Monte Carlo Analysis in R Using Package FME , 2010 .

[26]  Michael Schlüter,et al.  Numerical modeling of benthic processes in the deep Arabian Sea , 2000 .

[27]  B. Boudreau Is burial velocity a master parameter for bioturbation , 1994 .

[28]  B. Gustafsson,et al.  Beyond the Fe-P-redox connection: preferential regeneration of phosphorus from organic matter as a key control on Baltic Sea nutrient cycles , 2011 .

[29]  R. Berner Sulfate reduction and the rate of deposition of marine sediments , 1978 .

[30]  C. Reimers,et al.  Organic carbon dynamics and preservation in deep-sea sediments , 1985 .

[31]  C. Slomp,et al.  Modeling phosphorus cycling and carbon burial during Cretaceous Oceanic Anoxic Events , 2008 .

[32]  Philippe Van Cappellen,et al.  A multicomponent reactive transport model of early diagenesis: Application to redox cycling in coastal marine sediments , 1996 .

[33]  H. Jenkyns,et al.  Cretaceous oceanic anoxic events: causes and consequences , 2007 .

[34]  Bo G. Gustafsson,et al.  Sedimentary phosphorus dynamics and the evolution of bottom‐water hypoxia: A coupled benthic–pelagic model of a coastal system , 2011 .

[35]  J. Hedges,et al.  Sedimentary organic matter preservation: an assessment and speculative synthesis , 1995 .

[36]  K. Wallmann Feedbacks between oceanic redox states and marine productivity: A model perspective focused on benthic phosphorus cycling , 2003 .

[37]  Toby Tyrrell,et al.  The relative influences of nitrogen and phosphorus on oceanic primary production , 1999, Nature.

[38]  Karline Soetaert,et al.  Empirical relationships for use in global diagenetic models , 1997 .

[39]  Wang Yifeng,et al.  Metal cycling in surface sediments; modeling the interplay of transport and reaction , 1995 .

[40]  R. Jahnke,et al.  Evidence for enhanced phosphorus regeneration from marine sediments overlain by oxygen depleted waters , 1994 .

[41]  Andersen Fø Fate of organic carbon added as diatom cells to oxic and anoxic marine sediment microcosms , 1996 .

[42]  R. Glud Oxygen dynamics of marine sediments , 2008 .

[43]  R. Berner,et al.  A mathematical model for the early diagenesis of phosphorus and fluorine in marine sediments; apatite precipitation , 1988 .

[44]  Robert A. Berner,et al.  Early Diagenesis: A Theoretical Approach , 1980 .

[45]  C. Slomp,et al.  A key role for iron-bound phosphorus in authigenic apatite formation in North Atlantic continental platform sediments , 1996 .

[46]  Peter Berg,et al.  Dynamic Modeling of Early Diagenesis and Nutrient Cycling. A Case Study in an Artic Marine Sediment , 2003 .

[47]  D. Hammond,et al.  Early diagenesis of organic material in equatorial Pacific sediments: stpichiometry and kinetics , 1996 .

[48]  C. Slomp,et al.  Synchronous basin-wide formation and redox-controlled preservation of a Mediterranean sapropel , 2008 .

[49]  Clifford H. Mortimer,et al.  THE EXCHANGE OF DISSOLVED SUBSTANCES BETWEEN MUD AND WATER IN LAKES, II , 1941 .

[50]  H. D. Holland The chemistry of the atmosphere and oceans , 1978 .

[51]  W. Burnett,et al.  The present day formation of apatite in Mexican continental margin sediments , 1983 .

[52]  Peter M. J. Herman,et al.  Dynamic response of deep-sea sediments to seasonal variations: A model , 1996 .

[53]  A. Riboulleau,et al.  Does a strong pycnocline impact organic-matter preservation and accumulation in an anoxic setting? The case of the Orca Basin, Gulf of Mexico , 2009 .

[54]  Karline Soetaert,et al.  A Practical Guide to Ecological Modelling: Using R as a Simulation Platform , 2008 .

[55]  D. Burdige The biogeochemistry of manganese and iron reduction in marine sediments , 1993 .

[56]  Alfonso Mucci,et al.  Effects of progressive oxygen depletion on sediment diagenesis and fluxes: A model for the lower St. Lawrence River Estuary , 2007 .

[57]  R. Benner,et al.  Composition and cycling of marine organic phosphorus , 2001 .

[58]  Sergei Katsev,et al.  Factors controlling long-term phosphorus efflux from lake sediments: Exploratory reactive-transport modeling , 2006 .

[59]  R. Aller,et al.  Tracking particle-associated processes in nearshore environments by use of 234Th/238U disequilibrium , 1980 .

[60]  C. Slomp,et al.  Sedimentary organic carbon to phosphorus ratios as a redox proxy in Quaternary records from the Mediterranean , 2010 .

[61]  Yifeng Wang,et al.  Cycling of iron and manganese in surface sediments; a general theory for the coupled transport and reaction of carbon, oxygen, nitrogen, sulfur, iron, and manganese , 1996 .

[62]  D. Reed,et al.  A quantitative reconstruction of organic matter and nutrient diagenesis in Mediterranean Sea sediments over the Holocene , 2011 .

[63]  Hilairy E. Hartnett,et al.  Influence of oxygen exposure time on organic carbon preservation in continental margin sediments , 1998, Nature.

[64]  F. Sayles,et al.  Response of benthic oxygen demand to particulate organic carbon supply in the deep sea near Bermuda , 1994, Nature.

[65]  D. Canfield,et al.  Factors influencing organic carbon preservation in marine sediments. , 1994, Chemical geology.

[66]  Karline Soetaert,et al.  Solving Differential Equations in R: Package deSolve , 2010 .

[67]  Karline Soetaert,et al.  A model of early diagenetic processes from the shelf to abyssal depths , 1996 .

[68]  P. Bodelier,et al.  Phosphatases relieve carbon limitation of microbial activity in Baltic Sea sediments along a redox‐gradient , 2011 .

[69]  W. Burnett,et al.  Organic carbon cycling and modern phosphorite formation on the East Australian continental margin: an overview , 1990, Geological Society, London, Special Publications.

[70]  I. Jarvis,et al.  Phosphorite geochemistry: State of the art and environmental concerns , 1994 .

[71]  P. M. Williams,et al.  Reconciling particulate organic carbon flux and sediment community oxygen consumption in the deep North Pacific , 1992, Nature.

[72]  K. Föllmi,et al.  Phosphorus and the roles of productivity and nutrient recycling during oceanic anoxic event 2 , 2007 .

[73]  D. Canfield Sulfate reduction in deep-sea sediments. , 1991, American journal of science.

[74]  F. Grousset,et al.  Dysaerobic conditions during Heinrich events 4 and 5: Evidence from phosphorus distribution in a North Atlantic deep-sea core , 2002 .

[75]  Bernard P. Boudreau,et al.  Diagenetic Models and Their Implementation: Modelling Transport and Reactions in Aquatic Sediments , 1996 .

[76]  T. Ferdelman,et al.  Oxygen penetration deep into the sediment of the South Pacific gyre , 2009 .

[77]  Timothy M. Lenton,et al.  Periodic mid‐Cretaceous oceanic anoxic events linked by oscillations of the phosphorus and oxygen biogeochemical cycles , 2003 .