Abstract
Abstract. The sinking and decomposition of particulate organic matter are critical processes in the ocean's biological pump, but are poorly understood and crudely represented in biogeochemical models. Here we present a mechanistic particle remineralization and sinking model (PRiSM) that solves the evolution of the particle size distribution with depth. The model can represent a wide range of particle flux profiles, depending on the surface particle size distribution, the relationships between particle size, mass and sinking velocity, and the rate of particle mass loss during decomposition. The particle flux model is embedded in a data-constrained ocean circulation and biogeochemical model with a simple P cycle. Surface particle size distributions are derived from satellite remote sensing, and the remaining uncertain parameters governing particle dynamics are tuned to achieve an optimal fit to the global distribution of phosphate. The resolution of spatially variable particle sizes has a significant effect on modeled organic matter production rates, increasing production in oligotrophic regions and decreasing production in eutrophic regions compared to a model that assumes spatially uniform particle sizes and sinking speeds. The mechanistic particle model can reproduce global nutrient distributions better than, and sediment trap fluxes as well as, other commonly used empirical formulas. However, these two independent data constraints cannot be simultaneously matched in a closed P budget commonly assumed in ocean models. Through a systematic addition of model processes, we show that the apparent discrepancy between particle flux and nutrient data can be resolved through P burial, but only if that burial is associated with a slowly decaying component of organic matter such as might be achieved through protection by ballast minerals. Moreover, the model solution that best matches both data sets requires a larger rate of P burial (and compensating inputs) than have been previously estimated. Our results imply a marine P inventory with a residence time of a few thousand years, similar to that of the dynamic N cycle.
Highlights
The settling of organic particles to the deep sea has a profound effect on global ocean properties
We model the internal cycling of phosphorus (P) in the ocean as it is transformed between the particulate organic phosphorus (POP), dissolved organic phosphorus (DOP) and inorganic phosphate (PO4) pools (Fig. 3)
We discuss the results from a hierarchy of model configurations designed to evaluate the ability of particle remineralization and sinking model (PRiSM) to reproduce the time-averaged distribution of PO4
Summary
The settling of organic particles to the deep sea has a profound effect on global ocean properties. It sustains complex and diverse benthic and mesopelagic food webs, sequesters vast quantities of nutrients and CO2 away from the surface ocean and atmosphere, and creates a low-O2 layer that restricts marine habitat. If decomposition occurs deep in the water column, the regenerated nutrients may be stored for centuries, resurfacing at high latitudes where utilization by phytoplankton is relatively weak. T. DeVries et al.: Mechanistic global ocean particle model water column, the resupply will occur on faster timescales of seasons to decades, and may follow pathways to lower latitudes, where nutrient consumption is complete. The depths at which particles sink before being remineralized may have a large influence on marine productivity and carbon pump efficiency (Boyd et al, 2008; Buesseler and Boyd, 2009; Kwon et al, 2010)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
