Class #7: Thursday, July 15 Global wind systems

1. Class #7: Thursday, July 15Global wind systems Chapter 10 Class #7, Thursday, July 15, 2010

2. Wind: Global Systems Chapter 10 Class #7, Thursday, July 15, 2010

3. General Circulation of the Atmosphere • General refers to the average air flow, actual winds will vary considerably. • Average conditions help identify driving forces. • The basic cause of the general circulation is unequal heating of the Earth’s surface • Warm air is transferred from the Tropics to the Poles • Cool air is transferred from the Poles to the Tropics Class #7, Thursday, July 15, 2010

4. General Circulation of the Atmosphere • Single Cell Model • Assume • uniform water surface • Sun always directly overhead the Equator • Earth does not rotate Result: huge thermally direct convection cell (Hadley) • Three Cell Model • Allow earth to spin = three cells (Hadley, Ferrell, Polar) • Alternating belts of pressure starting with L at Equator • Alternating belts of wind with NE just North of Equator Class #7, Thursday, July 15, 2010

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7. General Circulation of the Atmosphere • Average Surface Wind and Pressure: The Real World • Semi-permanent high and lows • Northern vs. Southern Hemisphere • Major features shift seasonally with the high sun • North in July • South in December Class #7, Thursday, July 15, 2010

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11. General Circulation of the Atmosphere • General Circulation and Precipitation Patterns • Rain where air rises (low pressure) • Less rain where air sinks (high pressure) • Average Wind Flow and Pressure Patterns Aloft • North-South temperature and pressure gradient at high altitudes creates West-East winds, particularly at mid to high latitudes. Class #7, Thursday, July 15, 2010

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17. Class #7, Thursday, July 15, 2010 Fig. 1, p. 267

18. Class #7, Thursday, July 15, 2010 Fig. 2, p. 267

19. Jet Streams • 100-200 kt winds at 10-15km, thousands of km long, several 100 km wide and a few km thick (polar and subtropical) • Observations: Dishpan Experiment • Illustrates waves, with trough and ridge, develops in a rotating pan with heat on the exterior and cold at the center. Class #7, Thursday, July 15, 2010

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23. Jet Streams • Polar and Subtropical Jet • Established by steep temperature and pressure gradients between circulation cells. • Between tropical-mid-latitude cell (subtropical) and mid-latitude-polar cell (polar) • Gradients greatest at polar jet • Topic: Momentum • Low-latitudes: atmosphere gains momentum • High-latitudes: atmosphere losses momentum • Conservation of Momentum Class #7, Thursday, July 15, 2010

24. Jet Streams • Other Jet Streams • Tropical easterly jet stream • Low-level jet (nocturnal) • Polar night jet streams Class #7, Thursday, July 15, 2010

25. Atmosphere Ocean Interactions • Global Winds and Surface Ocean Currents • Ocean surface dragged by wind, basins react to high pressure circulation forming gyres • Cold current, flowing north to south, on west side of continent • Warm current, flowing south to north, on east side of continent • Oceanic front Class #7, Thursday, July 15, 2010

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27. Stepped Art Class #7, Thursday, July 15, 2010 Fig. 10-14, p. 273

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29. Atmosphere Ocean Interactions • Upwelling • Ekman spiral, Ekman transport • Water moving away from the coast causes upwelling • El Nino and the Southern Oscillation • El Nino: irregular warm episode off west coast of South America • Southern Oscillation: rise in pressure over W Pacific, fall in the E Pacific, equatorial countercurrent • ENSO • La Nina • teleconnection Class #7, Thursday, July 15, 2010

30. Class #7, Thursday, July 15, 2010 Fig. 10-16, p. 275

31. Class #7, Thursday, July 15, 2010 Fig. 10-17, p. 275

32. Class #7, Thursday, July 15, 2010 Fig. 10-18, p. 275

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43. Atmosphere Ocean Interactions • Pacific Decadal Oscillation • Reversal in Pacific Ocean temperatures • Warm = more Pacific storms • Cool = cool, wet NW North America, wetter over the Great Lakes, salmon fisheries decline Class #7, Thursday, July 15, 2010

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45. Atmosphere Ocean Interactions • North Atlantic Oscillation • Reversal of pressure in North Atlantic Ocean affecting weather in Europe and eastern coast of North America • Positive = strong Westerlies, storms in N Europe, wet and mild in eastern US • Negative = wet southern Europe and Mediterranean, cold and dry in eastern US Class #7, Thursday, July 15, 2010

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47. Atmosphere Ocean Interaction • Arctic Oscillation • Closely related to NAO • Pressure changes between Arctic and adjacent southern areas causes changes upper-level winds • Positive = mild winter in US and W Europe • Negative = cold US, cold dry Europe, wet Mediterranean Class #7, Thursday, July 15, 2010

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49. Wind: Global Systems Chapter 10 Class #7, Thursday, July 15, 2010