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Chapter 7 Ocean Circulation

Chapter 7 Ocean Circulation. Essentials of Oceanography 7 th Edition. Ocean currents. Surface currents Affect surface water within and above the pycnocline (10% of ocean water) Driven by major wind belts of the world Deep currents Affect deep water below pycnocline (90% of ocean water)

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Chapter 7 Ocean Circulation

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  1. Chapter 7 Ocean Circulation Essentials of Oceanography 7th Edition

  2. Ocean currents • Surface currents • Affect surface water within and above the pycnocline (10% of ocean water) • Driven by major wind belts of the world • Deep currents • Affect deep water below pycnocline (90% of ocean water) • Driven by density differences • Larger and slower than surface currents

  3. Measuring surface currents • Direct methods • Float meters • Intentional • Inadvertent • Propeller meters • Indirect methods • Pressure gradients • Satellites • Doppler flow meters Figure 7B

  4. Surface currents closely follow global wind belt pattern • Trade winds at 0-30º blow surface currents to the east • Prevailing westerlies at 30-60º blow currents to the west Figure 7-3

  5. Wind-driven surface currents Figure 7-4

  6. Current gyres • Gyres are large circular-moving loops of water • Subtropical gyres • Five main gyres (one in each ocean basin): • North Pacific • South Pacific • North Atlantic • South Atlantic • Indian • Generally 4 currents in each gyre • Centered at about 30º north or south latitude

  7. Current gyres • Gyres (continued) • Subpolar gyres • Smaller and fewer than subtropical gyres • Generally 2 currents in each gyre • Centered at about 60º north or south latitude • Rotate in the opposite direction of adjoining subtropical gyres

  8. Ekman spiral • Ekman spiral describes the speed and direction of flow of surface waters at various depths • Factors: • Wind • Coriolis effect Figure 7-6

  9. Ekman transport • Ekman transport is the overall water movement due to Ekman spiral • Ideal transport is 90º from the wind • Transport direction depends on the hemisphere • Internet visualization Figure 7-6

  10. Geostrophic flow and western intensification • Geostrophic flow causes a hill to form in subtropical gyres • The center of the gyre is shifted to the west because of Earth’s rotation • Western boundary currents are intensified Figure 7-7

  11. Western intensification of subtropical gyres • The western boundary currents of all subtropical gyres are: • Fast • Narrow • Deep • Western boundary currents are also warm • Eastern boundary currents of subtropical gyres have opposite characteristics

  12. Currents and climate • Warm current  warms air  high water vapor  humid coastal climate • Cool current  cools air  low water vapor  dry coastal climate Figure 7-8a

  13. Upwelling and downwelling • Vertical movement of water () • Upwelling = movement of deep water to surface • Hoists cold, nutrient-rich water to surface • Produces high productivities and abundant marine life • Downwelling = movement of surface water down • Moves warm, nutrient-depleted surface water down • Not associated with high productivities or abundant marine life

  14. Coastal upwelling and downwelling • Ekman transport moves surface water away from shore, producing upwelling • Ekman transport moves surface water towards shore, producing downwelling Figure 7-11

  15. Other types of upwelling • Equatorial upwelling • Offshore wind • Sea floor obstruction • Sharp bend in coastal geometry Equatorial upwelling Figure 7-9

  16. Antarctic surface circulation Figure 7-13

  17. Atlantic Ocean surface currents Figure 7-14

  18. North Atlantic Ocean circulation Figure 7-15

  19. The Gulf Stream and sea surface temperatures • The Gulf Stream is a warm, western intensified current • Meanders as it moves into the North Atlantic • Creates warm and cold core rings Figure 7-16

  20. Pacific Ocean surface currents Figure 7-17

  21. El Niño-Southern Oscillation (ENSO) • El Niño = warm surface current in equatorial eastern Pacific that occurs periodically around Christmastime • Southern Oscillation = change in atmospheric pressure over Pacific Ocean accompanying El Niño • ENSO describes a combined oceanic-atmospheric disturbance

  22. Normal conditions in the Pacific Ocean Figure 7-18a

  23. El Niño conditions (ENSO warm phase) Figure 7-18b

  24. La Niña conditions (ENSO cool phase; opposite of El Niño) Figure 7-18c

  25. The 1997-98 El Niño • Sea surface temperature anomaly map shows warming during severe 1997-98 El Niño • Internet site for El Niño visualizations • Current state of the tropical Pacific Figure 7-19a

  26. El Niño recurrence interval • Typical recurrence interval for El Niños = 2-12 years • Pacific has alternated between El Niño and La Niña events since 1950 Figure 7-20

  27. Effects of severe El Niños Figure 7-21

  28. Indian Ocean surface currents Northeast monsoon Southwest monsoon Figure 7-23

  29. Deep currents • Deep currents: • Form in subpolar regions at the surface • Are created when high density surface water sinks • Factors affecting density of surface water: • Temperature (most important factor) • Salinity • Deep currents are also known as thermohaline circulation

  30. Deep ocean characteristics • Conditions of the deep ocean: • Cold • Still • Dark • Essentially no productivity • Sparse life • Extremely high pressure

  31. Identification of deep currents • Deep currents are identified by measuring temperature (T) and salinity (S), from which density can be determined Figure 7-24

  32. Atlantic Ocean subsurface water masses Figure 7-25

  33. Conveyer-belt circulation Figure 7-27

  34. End of Chapter 7 Essentials of Oceanography 7th Edition

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