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Climate Change
Basics
The earth’s climate is predicted to
change because human activities are altering the chemical composition of the
atmosphere through the buildup of greenhouse gases—primarily carbon dioxide,
methane, and nitrous oxide. The heat-trapping property of these gases is
undisputed. Although uncertainty exists about exactly how earth’s climate
responds to these gases, global temperatures are rising.
What Are Greenhouse Gases?
Some greenhouse gases occur naturally in
the atmosphere, while others result from human activities. Naturally occuring
greenhouse gases include water vapor, carbon dioxide, methane, nitrous oxide,
and ozone. Certain human activities, however, add to the levels of most of
these naturally occurring gases:
Carbon
dioxide is released to the atmosphere when solid waste, fossil fuels
(oil, natural gas, and coal), and wood and wood products are burned.
Methane
is emitted during the production and transport of coal, natural gas, and oil.
Methane emissions also result from the decomposition of organic wastes in
municipal solid waste landfills, and the raising of livestock.
Nitrous
oxide is emitted during agricultural and industrial activities, as
well as during combustion of solid waste and fossil fuels.
Greenhouse
gases that are not naturally occurring include byproducts of foam production,
refrigeration, and air conditioning called chlorofluorocarbons (CFCs),
as well as hydrofluorocarbons (HFCs) and perfluorocarbons
(PFCs) generated by industrial processes.
Each
greenhouse gas differs in its ability to absorb heat in the atmosphere. HFCs
and PFCs are the most heat-absorbent. Methane traps over 21 times more heat
than carbon dioxide, and nitrous oxide absorbs 270 times more heat than carbon
dioxide. Often, estimates of greenhouse gas emissions are presented in units
of millions of metric tons of carbon equivalents (MMTCE), which weights each
gas by its GWP value, or Global
Warming Potential.
Our Changing Atmosphere
Energy
from the sun drives the earth’s weather and climate, and heats the earth’s
surface; in turn, the earth radiates energy back into space. Atmospheric
greenhouse gases (water vapor, carbon dioxide, and other gases) trap some of
the outgoing energy, retaining heat somewhat like the glass panels of a
greenhouse.
Without
this natural “greenhouse effect,” temperatures would be much lower than
they are now, and life as known today would not be possible. Instead, thanks
to greenhouse gases, the earth’s average temperature is a more hospitable
60°F. However, problems may arise when the atmospheric concentration of
greenhouse gases increases.
Since
the beginning of the industrial revolution, atmospheric concentrations of
carbon dioxide have increased nearly 30%, methane concentrations have more
than doubled, and nitrous oxide concentrations have risen by about 15%. These
increases have enhanced the heat-trapping capability of the earth’s
atmosphere. Sulfate aerosols, a common air pollutant, cool the atmosphere by
reflecting light back into space, however, sulfates are short-lived in the
atmosphere and vary regionally.
Why
are greenhouse gas concentrations increasing? Scientists generally believe
that the combustion of fossil fuels and other human activities are the primary
reason for the increased concentration of carbon dioxide. Plant respiration
and the decomposition of organic matter release more than 10 times the CO2
released by human activities; but these releases have always been in balance
with the carbon dioxide absorbed by plant photosynthesis. What has changed in
the last few hundred years is the additional release of carbon dioxide by
human activities. Energy burned to run cars and trucks, heat homes and
businesses, and power factories is responsible for about 80% of society's
carbon dioxide emissions, about 25% of U.S. methane emissions, and about 20%
of global nitrous oxide emissions. Increased agriculture, deforestation,
landfills, industrial production, and mining also contribute a significant
share of emissions. In 1994, the United States emitted about one-fifth of
total global greenhouse gases.
Estimating
future emissions is difficult, because it depends on demographic, economic,
technological, policy, and institutional developments. Several emissions
scenarios have been developed based on differing projections of these
underlying factors. For example, by 2100, in the absence of emissions control
policies, carbon dioxide concentrations are projected to be 30-150% higher
than today’s levels.
Changing Climate
Global
mean surface temperatures have
 increased
0.6-1.2°F since the late 19th century. The
20th century's 10 warmest years all occurred
within the last 15 years. Of these, 1998 was the warmest year on record. The
snow cover in the Northern Hemisphere and floating ice in the Arctic Ocean
have decreased. Globally, sea level has risen 4-10 inches over the past
century. Worldwide precipitation over land has increased by about one percent.
The frequency of extreme rainfall events has increased throughout much of the
United States.
Increasing
concentrations of greenhouse gases are likely to accelerate the rate of
climate change. Scientists expect that the average global surface temperature
could rise 1.6-6.3°F by 2100, with significant regional variation.
Evaporation will increase as the climate warms, which will increase average
global precipitation. Soil moisture is likely to decline in many regions, and
intense rainstorms are likely to become more frequent. Sea level is likely to
rise two feet along most of the U.S. coast.
Calculations
of climate change for specific areas are much less reliable than global ones,
and it is unclear whether regional climate will become more variable.
U.S. Environmental Protection Agency
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