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The central tropical Pacific is in hot water. That means El Niņo is knocking.
Five years after the onset of the most intense El Niņo on record, forecasters at the National Oceanic and Atmospheric Administration's Climate Prediction Center (CPC) are once again tracking conditions that herald another event.
Yet for all the improvements in detecting its signals, the phenomenon remains a forecasting challenge, researchers say.
"The El Niņo-Southern Oscillation is probably the most predictable large-scale climate fluctuation on the planet, but our crystal ball is still blurry," acknowledges Michael McPhaden, a research meteorologist at NOAA's Pacific Marine Environmental Laboratory in Seattle.
Forecasters monitoring the tropical Pacific first noticed El Niņo's feeble signals about the middle of last year, according to Vernon Kousky, a research meteorologist at the CPC.
"Things crept along until the end of last year, but now we're seeing more rapid development," he says. Unusually warm sea-surface temperatures are being recorded in the central tropical Pacific as a vast pool of warm water heads east.
This week, the CPC issued an El Niņo update indicating that during the next few weeks, waters off Peru and Ecuador should begin to warm, with El Niņo reaching full strength sometime within the next three months - although no one has any idea yet how strong it will be.
Formally known as the El Niņo-Southern Oscillation, the pattern repeats every four to five years. (See chart below for explanation of how the phenomenon occurs.) An El Niņo can last for 12 to 18 months.
While El Niņo has its most pronounced effect on the tropical Pacific and nearby regions, its reach is worldwide. By one estimate, the United States experienced an economic gain during the 1997-98 El Niņo of $16 billion and 650 fewer fatalities than might have otherwise occurred, because El Niņo brought milder than normal winters and suppressed the formation of Atlantic hurricanes.
Globally, however, researchers estimate that the event triggered $36 billion in damage and killed 22,000 people.
Thus, issues of strength, timing, and regional impact weigh heavily on researchers. The hope is that improved forecasts, properly used, can help reduce casualties and damage.
"Compared with the previous two or three events, 1997 proved very challenging," says Stephen Zebiak, director of modeling and prediction at the International Research Institute for Climate Prediction (IRI) at Columbia University's Lamont-Doherty Earth Observatory in Palisades, N.Y. "The magnitude was unprecedented and took forecasters by surprise. And our inability to anticipate changes more than a few months in advance was a problem."
Research that could improve the forecasts is focusing on the long-term and short-term patterns that affect air and sea circulation in the tropical Pacific.
One puzzle has been the rise of more frequent, more intense, and longer-lasting El Niņos since the mid-1970s.
Analyzing wind and water-current data collected between 1950 and 1999, Dr. McPhaden and colleague Dongxiao Zhang document a slowdown in Pacific Ocean circulation patterns that drive warm water from the tropics to higher latitudes, where it cools, sinks, and returns to the equator. There, upwelling drives the water back to the surface to be heated and to repeat the cycle.
This slowdown, reported in today's issue of the journal Nature, began in the 1970s, the two calculate. As a result, the reduced upwelling has allowed water temperatures at the surface along the equator to rise by about 0.8 degrees C.
This longer-term change could account for the trend in stronger El Niņos, which would have been nurtured in water already undergoing long-term warming. What isn't clear, the team notes, is whether this change is a result of global warming or natural variability. Records are too short, they say, to yield any clues.
Researchers also are becoming increasingly attuned to the importance of regional climate patterns that can mask or intensify El Niņo's farflung effects.
Typically, forecasters expect increased rainfall in equatorial East Africa, drought in Southern Africa, and weak summer monsoons in India during an El Niņo. In the 1997-98 episode, however, Kenya, Somalia, and Ethiopia got much more rain than expected. Lake Victoria's water level rose nearly two meters. Drought didn't materialize in Southern Africa, and India was drenched.
Clues in the Indian Ocean
The key may lie in the Indian Ocean basin. In 1999, researchers at IRI and the University of Colorado at Boulder published studies showing the Indian Ocean to have its own El Niņo-like cycle. The timing of the changes in the Pacific and Indian Oceans produced the unexpected effects.
The work has prompted calls to deploy a network of buoys similar to the Tau-Triton array, which stretches across the tropical Pacific. Such buoys, which gather atmospheric and oceanographic data, allow forecasters to monitor conditions and provide the long-term databaseresearchers can use to tease out patterns and trends.