Download Gloabal Air Circulation

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Core Case Study
Blowing in the Wind:
A Story of Connections
• Wind connects most
life on earth.
– Keeps tropics from
being unbearably
hot.
– Prevents rest of
world from freezing.
Figure 5-1
Factors Contributing to local climate:
•
•
•
•
•
•
Solar radiation
Earth’s rotation and path around the sun
Air circulation
Land masses and bodies of water
Circulation of ocean currents
Elevation of land masses
4 Major Factors affecting global air
circulation
• 1.) uneven heating of the earth’s surface by
the sun
• 2.) seasonal changes in temperature and
precipitation.
• 3.) rotation of the earth on its axis
• 4.) Properties of air, water, and land
1.) uneven heating of the earth’s
surface by the sun
• Picture shining a flashlight on a soccer ball
2.) seasonal changes in temperature
and precipitation.
• The earth’s axis is tilted.
• Northern and southern regions are either
tilted towards or away from the sun.
• This creates opposite seasons in the northern
and southern hemispheres.
Spring
(sun aims directly
at equator)
Winter
(northern hemisphere
tilts away from sun)
23.5 °
Solar
radiation
Summer
(northern hemisphere
tilts toward sun)
Fall
(sun aims directly at equator)
Fig. 5-3, p. 102
3.) rotation of the earth on its axis
• As the earth rotates around its north-south
axis, its equator spins faster than it’s polar
regions.
• As a result heated air masses rise above the
equator and winds moving north and south
eventually are deflected to the east and west.
• Coriolis effect.
Coriolis effect
• The direction of air movement in the resulting
atmospheric regions called cells sets up belts
of prevailing winds.
• Prevailing winds- major surface winds that
blow almost continuously and distribute air,
moisture, and dust over the earth’s surface.
4.) Properties of air, water, and land
• Heat from the sun evaporates ocean water
and transfers heat from the oceans to the
atmosphere
• Cyclical Convection Cells- circulate air, heat,
moisture vertically and from place to place in
the troposphere
LOW
PRESSURE
Heat released
radiates to space
Cool, dry
air
Falls, is compressed, warms
HIGH
PRESSURE
Condensation
and
precipitation
Rises, expands, cools
Warm,
dry air
Hot, wet
air
Flows toward low pressure,
picks up moisture and heat
HIGH
PRESSURE
Moist surface warmed by
sun
LOW
PRESSURE
Fig. 5-5, p. 103
Convection Cells
• Heat and moisture are distributed over the
earth’s surface by vertical air currents, which
form six giant convection cells at different
latitudes.
Cold deserts
Westerlies
Northeast trades
Forests
Hot deserts
Forests
Equator
Southeast trades
Westerlies
Hot deserts
Forests
Cold deserts
Fig. 5-4, p. 102
Cell 3 North
Cold,
dry air
falls
Moist air rises — rain
Polar cap
Arctic tundra
Cell 2 North
Evergreen
60° coniferous forest
Temperate deciduous
forest and grassland
Cool, dry
air falls
30° Tropical Desert
deciduous forest
0° Equator
Cell 1 North
Moist air rises,
cools, and releases
Moisture as rain
Tropical
rain forest
Tropical
deciduous forest
30°
60°
Desert
Temperate deciduous
forest and grassland
Cool, dry
air falls
Cell 2 South
Polar cap
Cold,
dry air
falls
Cell 1 South
Moist air rises — rain
Cell 3 South
Fig. 5-6, p. 103