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Atmospheric Circulation

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Presentation on theme: "Atmospheric Circulation"— Presentation transcript:

1 Atmospheric Circulation
Chapter 4 Atmospheric Circulation

2 Regions near the equator receive light at 90o
High latitudes receive light at low angles Earth

3 Regions near the equator receive light at 90o
High latitudes receive light at low angles Light energy is more concentrated near the equator. In other words, there is a greater flux per unit area (W/m2) Earth

4 Solar energy is concentrated near the equator
Image: Netherlands Center for Climate Research

5 absorbed solar energy Energy Latitude

6 absorbed solar energy Emitted IR energy Energy Latitude

7 More energy is absorbed near the equator than emitted
And more energy is emitted near the poles than is absorbed. absorbed solar energy Emitted IR energy Energy Latitude

8 net radiation surplus Energy Latitude

9 Excess energy at the equator is transferred towards the poles by convection cells
net radiation surplus Energy net radiation deficit Latitude

10 Solar energy received is greatest near the equator.
Energy is moved from the equator to the poles.

11 Solar energy received is greatest near the equator.
Energy is moved from the equator to the poles. Energy is transferred by wind and ocean currents

12 Air near the equator is warmed, and rises
solar radiation

13 H L H The rising air creates a circulation cell, called a Hadley Cell
solar radiation H Rising air  low pressure Sinking air  high pressure

14 Hadley Circulation Cell
Rising air is replaced Warm air rises

15 Hadley Circulation Cell
Air cools, sinks Rising air is replaced Warm air rises

16 Hadley Circulation Cell
Air cools, sinks Rising air is replaced Warm air rises HIGH HIGH LOW

17 The Earth would have two large Hadley cells, if it did not rotate.
--This is exactly what we think occurs on Venus (which rotates very slowly)! Rotation of the Earth leads to the Coriolis Effect This causes winds (and all moving objects) to be deflected: to the right in the Northern Hemisphere to the left in the Southern Hemisphere

18 Example of Coriolis effect: hurricanes
isobar (line of constant pressure) Hurricanes are low pressure centers Air moves from high pressure towards low pressure

19 Hurricanes: Northern hemisphere
L H H As the air moves in, it is deflected towards the right in the NH Resulting circulation is counter-clockwise

20 The Coriolis effect causes winds to deflect as they travel within circulation cells
This breaks up the two large Hadley cells into six smaller cells.

21 In the tropics, surface air is moving equatorward. It is
deflected to the right in the NH (left in the SH), giving rise to easterly flow (the trade winds) Easterlies

22 At midlatitudes, surface air is moving poleward. It is
deflected to the right in the NH (left in the SH), giving rise to westerly flow (the prevailing westerlies) Westerlies Westerlies

23                                                             Credit: NASA Credit: NASA

24 Hadley Circulation Cell
Air cools, sinks Rising air is replaced Warm air rises HIGH HIGH LOW

25 Rising air cools; the air’s capacity to hold water drops. Rain!
Air cools, sinks No rain in regions where air is descending Rising air is replaced Warm air rises HIGH HIGH LOW

26 : orbit-net.nesdis.noaa.gov/arad/ gpcp/maps/frontmap.gif

27

28 Caution: Zonal weather pattern is not completely true The pattern is disrupted by land-sea contrasts

29 Land heats and cools rapidly
Water heats and cools slowly

30 Sea Breezes Warm air rises Onshore wind DAY

31 Sea Breezes Warm air rises Onshore wind Offshore wind DAY NIGHT

32 Tibetian Plateau--Monsoon Circulation

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