1 / 22

Towards Reconciling Iron Supply and Demand in the Southern Ocean

Towards Reconciling Iron Supply and Demand in the Southern Ocean. Alessandro Tagliabue 1,2 J-B Sallée 3 , P.W. Boyd 4 , A.R. Bowie 5 , M. Lévy 6 , S. Swart 2 1 University of Liverpool, UK 2 CSIR , South Africa 3 British Antarctic Survey, UK 4 University of Otago , New Zealand

ranee
Download Presentation

Towards Reconciling Iron Supply and Demand in the Southern Ocean

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Towards Reconciling Iron Supply and Demand in the Southern Ocean Alessandro Tagliabue1,2 J-B Sallée3, P.W. Boyd4, A.R. Bowie5, M. Lévy6, S. Swart2 1University of Liverpool, UK 2CSIR, South Africa 3British Antarctic Survey, UK 4University of Otago, New Zealand 5University of Tasmania, Australia 6LOCEAN-IPSL, France a.tagliabue@liverpool.ac.uk

  2. Outline • Importance of physical processes • The Ferricline • Methods • Results • Ferricline distributions and relation to MLD • Estimating Fe inputs • Generalised View of Seasonal Fe Cycle • Summary and Conclusions

  3. Importance of physical processes • Southern Ocean productivity is Fe limited • Variability in production should be connected to changing degrees of Fe limitation • Much attention on external supplies • Large reservoirs below the mixed layer • Physical processes crucial in mediating transfer of Fe to the biota Boyd and Ellwood, 2010 Tagliabue et al., 2010

  4. Importance of physical processes • Two main physical mechanisms: • Winter Entrainment • Diapycnal Diffusion • Fe stock down to MLDMAX • Some ‘detrained’ during shallowing • dFe/dz at MLD • Kz (±10-5-10-4, m2 s-1)

  5. Importance of physical processes • Two main physical mechanisms: • Winter Entrainment • Diapycnal Diffusion • Sensitive to different processes • Fe stock down to MLDMAX • Some ‘detrained’ during shallowing • dFe/dz at MLD • Kz (±10-5-10-4, m2 s-1) Buoyancy vs momentum • Relative Roles unknown, implies that we don’t well know the climate sensitivity of Fe vertical supply

  6. The Ferricline • Key control on the vertical input of dFe • Similar to the ‘nitracline’ • dFe has • Longer remineralisation length scale • Particle Scavenging • Variable biological demand • Relation to MLD at basin scale unknown MLD ZFe Klunder et al. (2011)

  7. Methods • 3 complementary datasets: • New compilation of dFe measurements • ARGO co-location • Satellite estimates of iron utilisation

  8. Results

  9. Ferricline Depths 328±198m

  10. Ferricline Depths s0 at ferricline -Strong latitudinal trend -Modification to isopycnals drives much variability in ZFe

  11. Relation to MLD ZFe – MLD (m) 236±200m ZFe <MLD in 11 (8%) Or 4-19 cases at ±2s

  12. Vertical Gradients • The “ferricline” is the largest Fe source • Gradients sharper in the Atlantic Basin • Some regions do show some vertical gradient at the MLD

  13. Diapycnal Diffusion mmol m-2yr-1 Across ±2s and Kz estimates: 2-10 nmol m-2 d-1 OR 0.6-7.7 mmol m-2 yr-1

  14. Winter Entrainment • MLDs deepen in winter • ARGO provides us this information • But ZFe determinations generally from summer • Assume conservation of density • Use Fe, s measured to ‘project’ Fe onto s profile at time of MLDMAX

  15. Relation to MLDMAX ZFeW – MLDMAX (m) ~210m ZFe <MLD in 22 (17%) Or 9-40 cases at ±2s

  16. Entrainment mmol m-2yr-1 Across ±2s: 9.1-30.2 mmol m-2 yr-1 (0.6-7.7 mmol m-2 yr-1) “detrainment” dFe stock during shallowing accounted for from ARGO

  17. Supply versus Demand? • Iron utilisation includes recycled Fe • ‘feratios’ can be as low as 0.1 • Range of different Kz estimates • Sensitivity to Detrainment of winter dFe stock Boyd et al. 2012

  18. Supply vs Demand? Only - when kz is very high - fe-ratio very low can diapycnal supply meet demand at >50% of locations

  19. Supply vs Demand? Only - when detrainment losses are very high - fe-ratio very high Does entrainment NOT meet demand at >50% of locations

  20. Seasonal Cycling

  21. Summary and Conclusions • The ferricline is robustly decoupled from the MLD by ~200m • The ferricline depth has a strong relation to density • Only entrainment during winter is able to supply appreciable amounts of Fe over much of the S.O. • Low diapycnal inputs during summer result in a large reliance on recycled Fe in many locations • PP likely sensitive to processes that modulate winter mixing rather than summer stratification a.tagliabue@liverpool.ac.uk

  22. Density and the Ferricline

More Related