1 / 40

Atlantic Ocean Circulation and Climate: The Current View from the Geological Record

Atlantic Ocean Circulation and Climate: The Current View from the Geological Record. William Curry Woods Hole Oceanographic Institution AGU Fall Meeting December 13, 2006. -30 o C. -45 o C. Large Scale Ocean Circulation. Modern Atlantic Circulation. The Atlantic Heat Pump.

sona
Download Presentation

Atlantic Ocean Circulation and Climate: The Current View from the Geological Record

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. Atlantic Ocean Circulation and Climate: The Current View from the Geological Record William Curry Woods Hole Oceanographic Institution AGU Fall Meeting December 13, 2006

  2. -30o C -45o C

  3. Large Scale Ocean Circulation

  4. Modern Atlantic Circulation

  5. The Atlantic Heat Pump

  6. An Alternative Circulation

  7. Temperature Response • Strong cooling in North Atlantic • Warming everywhere else • No net global change Manabe and Stouffer, 1997

  8. 21,000 yBP -30o C -45o C

  9. Coring systems

  10. Planktonic foraminifera Benthic foraminifera

  11. CaCO3 [Ca, Mg, Cd, Zn] [16O,18O] [12C, 13C, 14C] Foraminiferal Calcite

  12. How do you use the fossil chemistry to reconstruct ocean circulation? • Mapping the spatial patterns of key nutrient tracers (d13C) to identify water mass position and geometry • Using the T-S sensitive tracers (d18O) to reconstruct ocean boundary density gradients

  13. NADW GEOSECS

  14. NADW Kroopnick (1985)

  15. Foraminiferal chemistry is controlled by the chemistry of the overlying water Ca13CO3 ~ S13CO2

  16. Core distribution 21,000 year old sample identified at each location Compiled from many sources

  17. Paleo “GEOSECS” Transect Curry and Oppo (2005) – compiled from many sources

  18. Curry and Oppo (2005)

  19. Curry and Oppo (2005)

  20. Section at 30o N

  21. Section at 30o S No data

  22. Summary of the Glacial Water Mass Geometry • Core of North Atlantic Deep Water shoaled from 2500 to 1500 m • Significantly greater Antarctic Bottom Water flowing north into the North Atlantic basin, influencing water as shallow as 2000m • Low d13C values found significantly shallower along the eastern margins – more southern ocean water or enhanced remineralization • The water mass geometry is confirmed by other proxy data like Cd/Ca and D14C

  23. Temperature and Salinity Characteristics of the Glacial Deep Waters Reconstructions of past salinity and d18Ow from pore water profiles in the deep Atlantic

  24. What were the water mass physical properties like? Pore Water profiles of salinity and d18O of sea water provide clues to the glacial water masses Adkins et al. (2002)

  25. Antarctic Bottom Water was >1 psu saltier than North Atlantic Deep Water Antarctic Bottom Water was ~0.5 per mil higher in d18Ow Both are opposite the modern gradients Adkins et al. (2002)

  26. Change in Salinity > 1 psu

  27. Dd18O anomaly at 30o S No data

  28. How did the rate of circulation change? Ocean margin density gradients and the Geostrophic Method

  29. Large Scale Ocean Circulation

  30. South Atlantic Circulation Lynch-Stieglitz et al. (2006)

  31. Determining past sea water density • Sea water • ~ f (T, S) • Foraminiferal CaCO3 • d18OCaCO3 ~ f (T, d18Owater) • and • d18Owater ~ S

  32. Density and d18O Densityst Lynch-Stieglitz et al. (1999)

  33. Density at 30o S South America Africa

  34. South America Africa Lynch-Stieglitz et al. (2006)

  35. Using an Inverse model The modern circulation can produce these density gradients but to accomplish this…….. the temperature and salinity characteristics of the South Atlantic water masses must have been very different. Gebbie and Huybers (2006)

  36. Or maybe the northward transport in the upper limb of the overturning circulation really was reduced…… • Consistent with a density gradient reduction across the Florida Straits (Lynch-Stieglitz et al., 1999) Holocene Glacial Transport

  37. Or maybe the northward transport in the upper limb of the overturning circulation really was reduced…… • Consistent with a reduction in the export of 231Pa from the North Atlantic (McManus et al., 2004) GISP2 NADW on H1 YD 0.093 Bermuda Rise NADW off

  38. What can we say about the glacial Atlantic Ocean circulation? Nutrient proxies depict the changes in geometry and position of the major water masses: • NADW reduced in total volume, shoaled by about 1000 m and southward penetration significantly reduced • AABW increased in total volume, influenced the water properties as shallow as 2000 m and penetrated much farther into the North Atlantic

  39. What can we say about the glacial Atlantic Ocean circulation? Pore water profiles constrain the salinity gradients in the deep Atlantic Ocean: • AABW was 1 psu higher in salinity than NADW, opposite the gradient observed in the modern ocean • A large d18O anomaly in the deep Atlantic is associated with this change in hydrography

  40. What can we say about the glacial Atlantic Ocean circulation? Ocean margin density gradients reflect changes in the mass transport: • The net northward transport in upper limb of the Atlantic Overturning Circulation was reduced • or • Thermocline salinities and temperatures were very different on either side of the South Atlantic

More Related