142 CHAPTER 7 Climate and Terrestrial Biodiversity
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CapricornPolar (ice) Subarctic (snow) Cool temperateWarm temperate Dry TropicalHighlandMajor upwelling zonesWarm ocean currentArctic
CircleCold ocean currentRiverActive Figure 7-2 Natural capital: generalized map of the earth’s current climate zones, show-
ing the major contributing ocean currents and drifts and upwelling areas (where currents bring nutrients from the
ocean bottom to the surface). Winds play an important role in distributing heat and moisture in the atmosphere,
which leads to such climate zones. Winds also cause currents that help distribute heat throughout the world’s
oceans. See an animation based on this figure at CengageNOW™. Question: Based on this map what is the gen-
eral type of climate where you live?60 °N60 °S30 °N30 °S0 °
EquatorSolar energyCold desertsCold desertsForestsForestsForestsHot desertsHot desertsWesterliesWesterliesNortheast tradesSoutheast tradesAir cools and
descends at
lower latitudes.Warm air rises and
moves toward the
poles.The highest solar energy
input is at the equator.Air cools and
descends at
lower latitudes.Figure 7-3 Global air circulation. The largest input of solar energy occurs at the equator. As this air is heated it rises
and moves toward the poles. However, the earth’s rotation deflects the movement of the air over different parts of
the earth. This creates global patterns of prevailing winds that help distribute heat and moisture in the atmosphere.