NEW
METHOD GREATLY IMPROVES U.S. SEASONAL FORECASTS A
new technique could raise the bar for predicting seasonal precipitation by 10
to 20 percent for all seasons in the United States, a NASA-funded study finds.
The
new method looks at changes in sea surface temperatures in various ocean basins,
and then weighs their individual impacts on regional climate to greatly increase
predictability of precipitation during all seasons. Changes in sea surface temperatures
strongly influence atmospheric winds, climate and weather. "The
paper presents results applied to the U.S. continent, where we show that the potential
predictability can be raised 10 to 20 percent above traditional methods,"
said William Lau, a senior researcher at NASA's Goddard Space Flight Center, and
lead author of the paper. "The scheme can be applied to other regions as
well. It raises the bar for seasonal and inter-annual climate forecasts."
The
paper will be presented on January 15 at the American Meteorology Society meeting
in Orlando, Fla. The study will also be published in an upcoming issue of the
journal Geophysical Research Letters. Currently,
scientists rely on climate patterns derived from global sea surface temperatures
to forecast precipitation for the U.S. winter. For example, rising warm moist
air creates tropical storms during El Niño years, a period of above average
temperatures in the waters in the central and eastern tropical Pacific. These
storms interact with the jet stream, causing it to steer southward during U.S.
winters. The altered jet stream directs more storms and rain over the west coast
and the southern states. When
climatologists use global sea surface temperatures to forecast U.S. winter precipitation,
the temperature of the tropical Pacific is the dominant force, and smaller signals,
like impacts from temperature changes in other ocean basins, get drowned out. While
the tropical Pacific largely dictates fall and winter precipitation levels, the
strength of that signal falls off by spring through the summer. This phenomenon
is called the 'spring-summer predictability barrier,' and nobody knows what causes
it. For that reason, summer climate predictions are very difficult to make. The
new technique takes a closer look at climate impacts from specific ocean basins,
including the tropical Pacific, the north Pacific, the tropical Atlantic, the
north Atlantic, and the Indian Ocean. Lau and his colleagues evaluated the individual
influences of each ocean basin on the climate of U.S. regions during each season.
Since
the tropical Pacific is the most dominant force in the winter, Lau's results for
the winter were similar to the traditional forecasts that use global sea surface
temperatures. In the winter, the tropical Pacific had the strongest influence
on the southern states, spanning the southwest, Mexico, the Gulf Coast, the southeast
and eastern seaboard. The northern Pacific had the strongest influence in the
Ohio Valley and the northwest, while the north Atlantic seemed to control the
northeastern seaboard, northern California, Idaho and Montana. In
the spring, the effects of the tropical Pacific wane and the northern Atlantic
begins to impact the northeast and the East Coast. In
the summer, the study finds a strong correlation between northern Pacific sea
surface temperatures and the climate of the region that stretches from the Gulf
coast of Texas to the northern Great Plains and the Midwest. The
study used 49 years of global climate data. Actual regional U.S. precipitation
amounts were ordered into three categories-above normal, normal and below normal.
To test their forecasts, Lau and his colleagues made predictions for each of the
49 years after building up their computer model with data from the remaining 48
years of observations. When the forecast and the actual observations matched,
the forecast was called a 'hit.' For the entire 49 years, their forecasts had
hits 45 percent or more in various regions of the US. For
all regions, regardless of the time of year, there was a 10 to 20 percent increase
in accuracy compared to traditional methods. The increases were most notable during
the spring and summer, greatly reducing the spring predictability barrier. Though
the method has yet to be used on a real-time forecast, it raises the bar for seasonal
precipitation prediction, Lau said. "We
hope to develop this into a bonafide forecast scheme to be used for regional climate
predictions," Lau said. EDITOR'S
NOTE: This presentation, session J1.20, will be given on Tuesday, January 15 at
4:00 PM at the 82nd Annual Meeting of the American Meteorological Society at the
Orange County Convention Center, Orlando, Fla.
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