Hi My Friends: A VUELO DE UN QUINDE EL BLOG., Acid rain. It was a problem that largely affected U.S. eastern
states. It began in the 1950s when Midwest coal plants spewed sulfur
dioxide and nitrogen oxides into the air, turning clouds--and
rainfall--acidic.
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Discovery
Acid Rain: Scourge of the Past or Trend of the Present?
Acid Rain: Scourge of the Past or Trend of the Present?
The following is part nine in a series on the National Science
Foundation's Long Term Ecological Research (LTER) Network. Visit parts one, two, three, four, five, six , seven and eight in this series.
Acid
rain. It was a problem that largely affected U.S. eastern states. It
began in the 1950s when Midwest coal plants spewed sulfur dioxide and
nitrogen oxides into the air, turning clouds--and rainfall--acidic.
As
acid rain fell, it affected everything it touched, leaching calcium
from soils and robbing plants of important nutrients. New England's
sugar maples were among the trees left high and dry.
Acid rain
also poisoned lakes in places like New York's Adirondack Mountains,
turning them into a witches' brew of low pH waters that killed fish and
brought numbers of fish-eating birds like loons to the brink.
Then
in 1970 the U.S. Congress imposed acid emission regulations through the
Clean Air Act, strengthened two decades later in 1990. By the 2000s,
sulfate and nitrate in precipitation had decreased by some 40 percent.
Has acid rain now blown over? Or is there a new dark cloud on the horizon?
In findings recently published in the journal Water Resources Research,
Charles Driscoll of Syracuse University and the National Science
Foundation's (NSF) Hubbard Brook Long Term Ecological Research (LTER)
site in New Hampshire reports that the reign of acid rain is far from
over.
It's simply "shape-shifted" into a different form.
Hubbard
Brook is one of 26 NSF LTER sites across the nation and around the
world in ecosystems from deserts to coral reefs to coastal estuaries.
Co-authors
of the paper are Afshin Pourmokhtarian of Syracuse University, John
Campbell of the U.S. Forest Service in Durham, N.H., and Katharine
Hayhoe of Texas Tech University. Pourmokhtarian is the lead author.
Acid
rain was first identified in North America at Hubbard Brook in the
mid-1960s, and later shown to result from long-range transport of sulfur
dioxide and nitrogen oxides from power plants.
Hubbard Brook research influenced national and international acid rain policies, including the 1990 Clean Air Act amendments.
Researchers at Hubbard Brook have continued to study the effects of acid rain on forest growth and on soil and stream chemistry.
Long-term
biogeochemical measurements, for example, have documented a decline in
calcium levels in soils and plants over the past 40 years. Calcium is
leaching from soils that nourish trees such as maples. The loss is
primarily related to the effects of acid rain (and acid snow).
Now
Hubbard Brook LTER scientists have discovered that a combination of
today's higher atmospheric carbon dioxide level and its atmospheric
fallout is altering the hydrology and water quality of forested
watersheds--in much the same way as acid rain.
"It's taken years
for New England forests, lakes and streams to recover from the
acidification caused by atmospheric pollution," says Saran Twombly, NSF
program director for long-term ecological research.
"It appears
that these forests and streams are under threat again. Climate change
will likely return them to an acidified state. The implications for
these environments, and for humans depending on them, are severe."
Climate
projections indicate that over the 21st century, average air
temperature will increase at the Hubbard Brook site by 1.7 to 6.5
degrees C, with increases in annual precipitation ranging from 4 to 32
centimeters above the average from 1970-2000.
Hubbard Brook
scientists turned to a biogeochemical model known as PnET-BGC to look at
the effects of changes in temperature, precipitation, solar radiation
and atmospheric carbon dioxide on major elements such as nitrogen in
forests.
The model is used to evaluate the effects of climate
change, atmospheric deposition, and land disturbance on soil and surface
waters in northern forest ecosystems.
It was created by linking
the forest-soil-water model PnET-CN with a biogeochemical sub-model,
enabling the incorporation of major elements like calcium, nitrogen,
potassium and others.
The results show that under a scenario of
future climate change, snowfall at Hubbard Brook will begin later in
winter, snowmelt will happen earlier in spring, and soil and stream
waters will become acidified, altering the quality of water draining
from forested watersheds.
"The combination of all these factors
makes it difficult to assess the effects of climate change on forest
ecosystems," says Driscoll.
"The issue is especially challenging
in small mountain watersheds because they're strongly influenced by
local weather patterns."
The Hubbard Brook LTER site has short,
cool summers and long, cold winters. Its forests are made up of northern
hardwood trees like sugar maples, American beeches and yellow birches.
Conifers--mostly balsam firs and red spruces--are more abundant at
higher elevations.
The model was run for Watershed 6 at Hubbard
Brook. "This area has one of the longest continuous records of
meteorology, hydrology and biogeochemistry research in the U.S.," says
Pourmokhtarian.
The watershed was logged extensively from 1910 to 1917; it survived a hurricane in 1938 and an ice storm in 1998.
It may have more to weather in the decades ahead.
The
model showed that in forest watersheds, the legacy of an accumulation
of nitrogen, a result of acid rain, could have long-term effects on soil
and on surface waters like streams.
Changes in climate may also
alter the composition of forests, says Driscoll. "That might be very
pronounced in places like Hubbard Brook. They're in a transition forest
zone between northern hardwoods and coniferous red spruces and balsam
firs."
The model is sensitive to climate that is changing now--and climate changes expected to occur in the future.
In
scenarios that result in water stress, such as decreases in summer soil
moisture due to shifts in hydrology, the end result is further
acidification of soil and water.
-- | Cheryl Dybas, NSF (703) 292-7734 cdybas@nsf.gov |
Related Websites
NSF LTER Network: http://www.lternet.edu/
NSF Hubbard Brook LTER Site: http://www.hubbardbrook.org/
Science, Engineering and Education for Sustainability NSF-Wide Investment (SEES): http://www.nsf.gov/funding/pgm_summ.jsp?pims_id=504707
NSF LTER Network: http://www.lternet.edu/
NSF Hubbard Brook LTER Site: http://www.hubbardbrook.org/
Science, Engineering and Education for Sustainability NSF-Wide Investment (SEES): http://www.nsf.gov/funding/pgm_summ.jsp?pims_id=504707
Guillermo Gonzalo Sánchez Achutegui
ayabaca@gmail.com
ayabaca@hotmail.com
ayabaca@yahoo.com
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