19/02/2008
Scientists
Warn of Profound Changes in World's
Oceans.
BOSTON,
Massachusetts, February 19, 2008 (ENS)
- Climate change is transforming the
world's oceans by increasing the temperature
and acidity of seawater, and altering
atmospheric and oceanic circulation,
reported a panel of scientists this
week at the American Association for
the Advancement of Science, AAAS, annual
meeting in Boston.
"The vastness
of our oceans may have engendered a
sense of complacency about potential
impacts from global climate change,"
said Dr. Jane Lubchenco, a marine biologist
at Oregon State University, who moderated
the panel. "The world's oceans
are undergoing profound physical, chemical
and biological changes whose impacts
are just beginning to be felt."
Panelist Gretchen Hofmann,
a molecular physiologist at the University
of California-Santa Barbara, describes
the situation as "multiple jeopardy."
"Ocean ecosystems are facing new
stresses and new combinations of
stress," Hofmann
said. "The water is warmer, circulation
patterns are changing in unpredictable
ways, and oceans are becoming acidic."
Michael Behrenfeld,
an oceanographer from Oregon State University,
is studying relationships between climate
and the global activity of ocean plants
called phytoplankton.
"Phytoplankton
are of tremendous human importance because
their photosynthesis yields oxygen for
us to breathe and they are the base
of the ocean food webs that support
our global fisheries," Behrenfeld
explained.
Despite their microscopic
size, ocean phytoplankton are responsible
for about half of the photosynthesis
on Earth, a process that removes carbon
dioxide from the atmosphere and converts
it into organic carbon to fuel nearly
every ocean ecosystem.
Using NASA satellites,
Behrenfeld and other scientists are
tracking changes in phytoplankton on
a global basis and finding that warming
ocean temperatures are linked to decreasing
photosynthesis.
Satellites aid understanding
of the link between climate and ocean
biology because they provide measurements
of the whole planet on a daily basis,
yet now the Behrenfeld worries that
"we are facing the end of NASA
ocean biology satellites because of
budget cutbacks or new priorities."
"Instead of facing
the end of these critical missions and
becoming blind to the changes occurring
in our oceans," Behrenfeld said,
"we should be building even better
ones to see more clearly than we have
in the past, and to gauge the potential
consequences of climate change on ocean
productivity."
The panelists also
called for greater investment in ocean
observing systems that would allow scientists
to better measure changing in the ocean
ecosystem, including large-scale circulation
and coastal upwelling systems around
the world.
Rising greenhouse gas
emissions are warming the world's oceans
and providing a new threat to coral
reefs, which already are among the most
threatened of all marine ecosystems,
the panelists say.
Even modest warming
of a degree or two above normal maximum
temperatures can cause a breakdown in
the relationship between corals and
their symbiotic algae, zooxanthellae,
said Nancy Knowlton, a marine biologist
with the Smithsonian Institution.
Without zooxanthellae,
corals appear white, or "bleached,"
and grow more slowly. They also are
more susceptible to disease and may
not reproduce.
In 1998 there were
worldwide mass bleaching events, Knowlton
pointed out, affecting 80 percent of
the corals in the Indian Ocean, 20 percent
of which died.
In 2005, severe bleaching
occurred over much of the Caribbean
as a result of overly warm water temperatures.
"We have already
lost some 80 percent of the reef corals
in the Caribbean over the last three
decades, and losses in the Pacific Ocean
also are widespread and severe,"
Knowlton said.
"Reefs are like
cities, with some parts growing and
some parts being destroyed, and only
when net growth is positive can reefs
persist. These reefs already are under
threat to overfishing and local pollution
and unless drastic action to reduce
greenhouse gas emissions is taken soon,"
she said, "these reefs will cease
to exist as we know them."
These same greenhouse
gas emissions also are creating dramatic
buildup of atmospheric carbon dioxide,
CO2, which is making the world's oceans
more acidic, said panelist Scott Doney
of the Woods Hole Oceanographic Institution.
Current CO2 levels
of 380 parts per million already are
30 percent higher than pre-industrial
values and many scientific models predict
that those rates will triple by the
end of the century under "business
as usual" scenarios.
While much of the scientific
attention on ocean acidification has
looked at the impact of coral reefs,
the potential danger to other marine
ecosystems is equally severe, Doney
said.
"Ocean acidification
harms plants and animals that form shells
from calcium carbonate," he said.
"Calcifying organisms include not
just corals, but many plankton, pteropods
[marine snails], clams and oysters,
and lobsters. Many of these organisms
provide critical food sources or habitats
for other organisms and the impact of
acidification on food webs and higher
trophic levels is not well understood."
"Newly emerging
evidence suggests that larval and juvenile
fish may also be susceptible to changes
in ocean pH levels," Doney added.
"Ocean acidification is rapidly
becoming a real problem."
Klaus Keller of Penn
State University reported on the economic
costs and benefits of effective ocean
observing systems to detect changes
in the North Atlantic.
Jack Barth, an oceanographer
at Oregon State University, said low
oxygen dead zones that have appeared
on the Pacific Northwest coast since
2000 are unprecedented over the last
five decades of scientific observation
and likely linked to stronger, more
persistent winds that are expected to
occur with global warming, he said.
The California Current
System provides a case study for similar
changes in coastal upwelling zones off
South America, southern Africa and northern
Africa, Barth said.
"One of the things
we've observed is how wind patterns
have changed and greatly affected upwelling,"
Barth said. "Two decades ago, the
winds would last for three or four days,
and then subside. Now they persist for
20 to 40 days before settling down.
This creates significant impacts on
upwelling and biological productivity,
but these impacts can swing wildly from
one extreme to another and have been
difficult to predict."
The AAAS symposium
was organized by the Partnership for
Interdisciplinary Studies of Coastal
Oceans, a multi-university research
effort headquartered at Oregon State
University.
Copyright Environment
News Service (ENS) 2008.
