1. Ch 20
Part 2

2. CLIMATE CHANGE AND HUMAN ACTIVITIES
Evidence that the earth’s troposphere is warming, mostly because of human actions:
The 20th century was the hottest century in the past years.
Since 1900, the earth’s average tropospheric temperature has risen 0.6 C°.
Over the past 50 years, Arctic temperatures have risen almost twice as fast as those in the rest of the world.
Glaciers and floating sea ice are melting and shrinking at increasing rates.

3. CLIMATE CHANGE AND HUMAN ACTIVITIES
Warmer temperatures in Alaska, Russia, and the Arctic are melting permafrost releasing more CO2 and CH4 into the troposphere.
During the last century, the world’s sea level rose by cm, mostly due to runoff from melting and land-based ice and the expansion of ocean water as temperatures rise.

4. The Scientific Consensus about Future Climate Change
There is strong evidence that human activities will play an important role in changing the earth’s climate during this century.
Coupled General Circulation Models (CGCMs) couple, or combine, the effects of the atmosphere and the oceans on climate.

5. CGCM of the Earth’s Climate
Simplified model of major processes that interact to determine the average temperature and greenhouse gas content of the troposphere.
Figure 20-6

6. Green- house gases Land and soil biotoa Long-term storage
Sun
Troposphere
Cooling
from
increase
Green-
house
gases
Heat and
CO2 emissions
Aerosols
CO2 removal
by plants and
soil organisms
CO2 emissions from land clearing,
fires, and decay
Heat and
CO2 removal
Warming
from
decrease
Ice and snow cover
Shallow ocean
Land and soil biotoa
Figure 20.6
Natural capital: simplified model of some major processes that interact to determine the average temperature and greenhouse gas content of the troposphere and thus the earth’s climate.
Long-term
storage
Natural and human emissions
Deep ocean
Fig. 20-6, p. 469

7. The Scientific Consensus about Future Climate Change
Measured and projected changes in the average temperature of the atmosphere.
Figure 20-7

8. Figure 20.7
Natural capital degradation: comparison of measured changes in the average temperature of the atmosphere at the earth’s surface between 1875 and 2005 and the projected range of temperature increase during the rest of this century. QUESTION: If these projections are valid, list three ways this will affect your lifestyle. (Data from U.S. National Academy of Sciences, National Center for Atmospheric Research, and Intergovernmental Panel on Climate Change, Hadley Center for Climate Prediction and Research)
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VIDEO

9. Why Should We Be Concerned about a Warmer Earth?
A rapid increase in the temperature of the troposphere during this century would give us little time to deal with its harmful effects.
As a prevention strategy scientists urge to cut global CO2 emissions in half over the next 50 years.
This could prevent changes in the earth’s climate system that would last for tens of thousands of years.

10. FACTORS AFFECTING THE EARTH’S TEMPERATURE
Some factors can amplify (positive feedback) and some can dampen (negative feedback) projected global warming.
There is uncertainty about how much CO2 and heat the oceans can remove from the troposphere and how long the heat and CO2 might remain there.
Warmer temperatures create more clouds that could warm or cool the troposphere.

11. Effects of Higher CO2 Levels on Photosynthesis
Increased CO2 in the troposphere can increase plant photosynthesis (PS) but:
The increase in PS would slow as the plants reach maturity.
Carbon stored by the plants would be returned to the atmosphere as CO2 when the plants die.
Increased PS decreases the amount of carbon stored in the soil.
Tree growth may temporarily slow CO2 emissions in the S. Hemisphere but is likely to increase CO2 emissions in the N. Hemisphere.

12. FACTORS AFFECTING THE EARTH’S TEMPERATURE
Aerosol and soot pollutants produced by human activities can warm or cool the atmosphere, but such effects will decrease with any decline in outdoor air pollution.
Warmer air can release methane gas stored in bogs, wetlands, and tundra soils and accelerate global warming.

13. EFFECTS OF GLOBAL WARMING
A warmer climate would have beneficial and harmful effects but poor nations in the tropics would suffer the most.
Some of the world’s floating ice and land-based glaciers are slowly melting and are helping warm the troposphere by reflecting less sunlight back into space.

14. EFFECTS OF GLOBAL WARMING
Between 1979 and 2005, average Arctic sea ice dropped 20% (as shown in blue hues above).
Figure 20-8

15. * Russia North Greenland pole Alaska (U.S.) Canada PLAY VIDEO
Figure 20.8
Science: satellite data showing Arctic sea ice between 1979 and The white area shows a moving average of Arctic sea ice between 2003 and The darker blue surrounding the white area is the moving average for the sea ice between 1979 and Between 1979 and 2005, average Arctic sea ice dropped 20%—a loss in area about the size of the U.S. state of Texas. The decrease in light-colored ice reflects less incoming solar energy back into space and can heat the troposphere. This in turn can cause more ice to melt and raise temperatures more in a runaway positive feedback cycle. QUESTION: List three impacts that this and continued melting of Arctic sea ice might have on your lifestyle. (Goddard Space Flight Center, NASA)
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VIDEO

16. Rising Sea Levels
During this century rising seas levels are projected to flood low-lying urban areas, coastal estuaries, wetlands, coral reefs, and barrier islands and beaches.
Figure 20-10

17. Mean Sea-Level Rises (centimeters)
High Projection
New Orleans,
Shanghai, and
other low-lying
cities largely
underwater
Mean Sea-Level Rises (centimeters)
Medium
Projection
More than a third of
U.S. wetlands underwater
Figure 20.10
Natural capital degradation: projected rise in global sea levels during this century. With such a rise, flooding and coastal erosion would be especially severe in heavily populated coastal areas of the tropics and warm temperate regions. Thirteen of the world’s largest 20 cities are located at sea level. QUESTION: List three ways that this projected rise in sea level could affect your lifestyle. (Data from Intergovernmental Panel on Climate Change, 2000)
Low Projection
Year
Fig , p. 475

18. Rising Sea Levels
Changes in average sea level over the past 250,000 years based on data from ocean cores.
Figure 20-9

19. present sea level (meters) Height above or below
Today’s sea level
present sea level (meters)
Height above or below
Height above or below present sea level (feet)
Figure 20.9
Changes in average sea level over the past 250,000 years based on data from cores removed from the ocean bottom. The coming and going of glacial periods (ice ages) largely determine the rise and fall of sea level. As glaciers melted and retreated since the peak of the last glacial period about 18,000 years ago (Figure 4-6, p. 89), the earth’s average sea level has risen about 125 meters (410 feet). (Adapted from Tom Garrison, Oceanography: An Invitation to Marine Science, 3/E, © Brooks/Cole)
Years before present
Present
Fig. 20-9, p. 475

20. Rising Sea Levels
If seas levels rise by 9-88cm during this century, most of the Maldives islands and their coral reefs will be flooded.
Figure 20-11

21. Changing Ocean Currents
Global warming could alter ocean currents and cause both excessive warming and severe cooling.
Figure 20-12

22. Warm, shallow current Cold, salty, deep current PLAY VIDEO
Figure 20.12
Natural capital: a connected loop of shallow and deep ocean currents stores CO2 in the deep sea and transports warm and cool water to various parts of the earth. This loop results when ocean water in the North Atlantic near Iceland is dense enough (because of its salt content and cold temperature) to sink to the ocean bottom, flow southward, and then move eastward to well up in the warmer Pacific. A shallower return current aided by winds then brings warmer and less salty—and thus less dense—water to the Atlantic. This water can cool and sink to begin the cycle again. A warmer planet would be a rainier one, which, coupled with melting glaciers, would increase the amount of freshwater flowing into the North Atlantic. This could slow or even jam this loop by diluting the saltwater and making it more buoyant (less dense) and less prone to sinking. Historical evidence suggests that such shifts in ocean currents have sometimes taken place in a matter of years or decades. QUESTION: How might your lifestyle be affected if this loop slows down in your lifetime?
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VIDEO
Fig , p. 476