By J. Marshall Shepherd and John Knox*
ATHENS, GEORGIA
– In the waning weeks of the North American hurricane season – a time when a
superstorm is not expected to cause widespread damage to the eastern coast of
the United States – Hurricane Sandy is a grim reminder of the menace of extreme
weather events. With the lowest central pressure of the 2012 hurricane season,
Sandy may have caused up to $20 billion in damages, making it one of the
costliest superstorms in history.
Illustration by Margaret Scott
Sandy
interacted with a weather system moving toward it from the east, posing
difficult challenges for forecasters and nearly unprecedented weather
conditions for the region. A similar storm hit New England 20 years ago. But
Sandy was worse, delivering hurricane-strength winds, drenching rains, and
severe coastal flooding throughout the populous mid-Atlantic and northeast
corridor.
Some people
will, of course, try to link Sandy with climate change. A similar rush to
judgment occurred in the wake of massive tornado outbreaks in the US in recent
years, even though the scientific literature does not offer strong support for
such a connection. So, from the perspective of climate change, it is best to
take a measured view of Sandy, lest hasty reaction harm scientific credibility.
But that is
little cause for comfort. According to the giant insurance company Munich Re,
weather and climate disasters contributed to more than one-third of a trillion
dollars in damage worldwide in 2011, and this year’s total may rival that
amount. There is growing evidence of links between climate change and sea-level
rise, heat waves, droughts, and rainfall intensity, and, although scientific
research on hurricanes and tornadoes is not as conclusive, that may be
changing.
Indeed, recent
reports by the United Nations’ Intergovernmental Panel on Climate Change (IPCC)
and other scientific literature suggest that the intensity of tropical cyclones (that is, hurricanes)
will increase as a result of warmer waters. And our atmosphere and
oceans are, indeed, warming, with substantial residual heat stored in the
ocean, to be released at some future time. A few studies have even suggested
that tropical cyclones may be “wetter.” It is quite certain that sea levels
have risen over the last century, and continue to rise, in response to changing
climate. And storm surges now ride on these elevated sea levels, amplifying
flooding losses where they strike.
Sea surface
temperatures along the US northeast coast are about five degrees Fahrenheit
above average, which helped to intensify Sandy just prior to landfall. At this
point, it is premature to link the storm’s severity to warmer sea-surface
temperatures, because regional variability is known to occur. But the link
certainly is plausible.
Moreover, sea
levels along the US northeast coast are rising up to four times faster than the
global average, making the region more vulnerable to storm surges and flooding.
And here the bottom line is that any coastal storm system will produce more
flooding because of sea level rise.
It should also
be noted that an atmospheric weather pattern known as a “block,” a persistent
area of high pressure that may have led to record melting in Greenland, was
most likely the reason that Sandy moved inland rather than out to sea. It is
too early to tell whether this blocking pattern is a manifestation of weather
variability, a short-term climate variation, or the result of climate change.
Advances in
numerical weather forecasting during the past several decades have extended our
ability to “see” into the future. In September 1938, before all of these
advances, a hurricane devastated much of New England. No warnings were issued
prior to its arrival. Today, thanks to satellites, weather balloons,
supercomputers, and skilled forecasters, we can anticipate hazardous weather up
to a week in advance. Similar advances in climate modeling are occurring,
thanks to methodological improvements and better data.
At a minimum,
we must ensure that world-class weather and climate-modeling centers have the
necessary funding and manpower to implement the most advanced forecasting
techniques. Numerical weather forecasting was invented in the US, but today
other countries have developed extremely high modeling capacity. For example,
the European
Center for Medium-Range Weather Forecasts, in Great Britain, was
targeting an East Coast landfall for Sandy days ahead of the best American
model.
The world will
need more cooperation in the coming years, as climate change begins to interact
with and exacerbate extreme weather events, in order to gain the lead-time
needed to prepare for disasters. We will also need the collaboration among
governments, the private sector, and academia that often leads to improvements
in forecasting.
Scientific
meetings are key forums for sharing research, vetting new methodologies, and
forging new partnerships. Many occur on an international basis, and we need to
encourage such discourse, even in tough times for government budgets. It is
reasonable to ask how well we would be able to predict or assess a storm like
Sandy without the knowledge and capacity gained through such international
collaboration.
We do not know
whether superstorms like Sandy are harbingers of a “new normal” in the uneasy
and unpredictable relationship between climate change and extreme weather
events. That does not mean that there is not or cannot be such a connection,
but rather that the scientific research needed to prove (or disprove) it must
still be conducted. That is how good science works. Sandy has provided a
powerful demonstration of the need to support it.
*J. Marshall Shepherd
J. Marshall
Shepherd, Director of the Atmospheric Sciences Program at the University of
Georgia
John Knox
John Knox, a
professor of geography at the University of Georgia
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