Ironing Out Fe Residence Time in the Dynamic Upper Ocean

Abstract: Although iron availability has been shown to limit ocean productivity and influence marine carbon cycling, the rates of processes driving iron's removal and retention in the upper ocean are poorly constrained. Using 234 Th-and sediment-trap data, most of which were collected through international GEOTRACES efforts, we perform an unprecedented observation-based assessment of iron export from and residence time in the upper ocean. The majority of these new residence time estimates for total iron in the surface o… Show more

“…These high source fluxes need to be compensated by efficient scavenging and subsequent removal via burial in the sediments to reproduce the distribution and global mean inventory in DFe observations. This is in general agreement with observational studies focusing on the surface layer (Black et al, 2020;Sarthou et al, 2003). For example, Black et al (2020) estimated similar residence times throughout the global surface ocean (0-250 meters) for DFe ranging from approximately 1 month to 4 years depending on the region and specific iron pools considered, although noting that the uncertainties remain large (i.e.…”

“…This is in general agreement with observational studies focusing on the surface layer (Black et al, 2020;Sarthou et al, 2003). For example, Black et al (2020) estimated similar residence times throughout the global surface ocean (0-250 meters) for DFe ranging from approximately 1 month to 4 years depending on the region and specific iron pools considered, although noting that the uncertainties remain large (i.e. equal or greater than the absolute value of the estimate in each region).…”

“…As a result, the range of residence times estimated by the current global marine iron cycle models ranges from less than a decade to multiple centuries (Tagliabue et al, 2016), which limits our ability to confidently predict the impact of changes to the marine iron cycle on productivity in a future ocean. Observational estimates fall within a similar range (Johnson et al, 1997), noting that more recent studies estimate much shorter residence times in the upper ocean (~10 days -4 years) (Croot et al, 2004;Sarthou et al, 2003) depending on the dynamics, iron pools considered, and source inputs in different regions (Black et al, 2020).…”

“…normalized standard deviation values fall below the value one; Figure 7). High variance in the global dataset may not reflect mean climatological conditions simulated by the steady-state model results given the highly dynamic nature of DFe cycling particularly in the surface ocean (Black et al, 2020), and the limitations of spatial and temporal sparsity of the dataset. But note that the standard deviation was significantly improved in our best model simulation with variable ligands and high source/scavenging fluxes (#5 Atm+SedFeHigh_LigVar; see Figure 7).…”

Constraining global marine iron source and scavenging fluxes with GEOTRACES dissolved iron measurements in an ocean biogeochemical model

“…These high source fluxes need to be compensated by efficient scavenging and subsequent removal via burial in the sediments to reproduce the distribution and global mean inventory in DFe observations. This is in general agreement with observational studies focusing on the surface layer (Black et al, 2020;Sarthou et al, 2003). For example, Black et al (2020) estimated similar residence times throughout the global surface ocean (0-250 meters) for DFe ranging from approximately 1 month to 4 years depending on the region and specific iron pools considered, although noting that the uncertainties remain large (i.e.…”

“…This is in general agreement with observational studies focusing on the surface layer (Black et al, 2020;Sarthou et al, 2003). For example, Black et al (2020) estimated similar residence times throughout the global surface ocean (0-250 meters) for DFe ranging from approximately 1 month to 4 years depending on the region and specific iron pools considered, although noting that the uncertainties remain large (i.e. equal or greater than the absolute value of the estimate in each region).…”

“…As a result, the range of residence times estimated by the current global marine iron cycle models ranges from less than a decade to multiple centuries (Tagliabue et al, 2016), which limits our ability to confidently predict the impact of changes to the marine iron cycle on productivity in a future ocean. Observational estimates fall within a similar range (Johnson et al, 1997), noting that more recent studies estimate much shorter residence times in the upper ocean (~10 days -4 years) (Croot et al, 2004;Sarthou et al, 2003) depending on the dynamics, iron pools considered, and source inputs in different regions (Black et al, 2020).…”

“…normalized standard deviation values fall below the value one; Figure 7). High variance in the global dataset may not reflect mean climatological conditions simulated by the steady-state model results given the highly dynamic nature of DFe cycling particularly in the surface ocean (Black et al, 2020), and the limitations of spatial and temporal sparsity of the dataset. But note that the standard deviation was significantly improved in our best model simulation with variable ligands and high source/scavenging fluxes (#5 Atm+SedFeHigh_LigVar; see Figure 7).…”

Constraining global marine iron source and scavenging fluxes with GEOTRACES dissolved iron measurements in an ocean biogeochemical model

“…Additional uncertainty remains over the fate of this Fe even after it reaches the euphotic zone. A recent global compilation of flux calculations suggests that Fe undergoes very rapid scavenging (time scale <1 yr) in particle-rich surface waters (Black et al, 2020), further limiting its availability to phytoplankton.…”

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