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______________________
Jacob Bjerknes - the Synthesizer
It took another 50 years, but in the late 1960s a Norwegian meteorologist, Jacob Bjerknes,
put the whole picture together. As a professor at the University of California, he was the
first to see a connection between unusually warm sea-surface temperatures and the weak
easterlies and heavy rainfall that accompany low-index conditions.
Relying upon the data of 1957, Bjerknes went further than Walker in stating his thesis on
El Niņo. Only a thin sheet of water separates the atmosphere from the ocean depths. Thus,
the difference in temperature between that sea surface and the air above it is what causes
heat to flow and water vapor to be exchanged. Bjerknes proposed in 1966 that the relaxed
trade winds of 1957 not only caused the appearance of unusually warm surface waters over
the tropical Pacific, but were in turn caused by the increase in sea surface temperatures
(SST) during that year. This amazing circular argument implied that this phenomenon was
neither strictly atmospheric nor oceanic but a product of interactions of the two.
Dr. Richard T. Barber beautifully summed it up when he said, "The ocean is clearly
driving the atmosphere."
______________________
Sleepless Polar Bears
The 1976-77 El Niņo, which was no slouch, brought severe cold over the eastern United
States, and drought in the west. Polar regions were so cold, the bears did not hibernate.
During the month of January 1977, 85 percent of the ground was covered by snow at some
time during the month. Miami, Fla., reported snow flurries, and snow drifts in Buffalo,
N.Y., were two stories high.
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Analysis of His Findings
The differences between the two distant pressure systems (Tahiti minus Darwin) have been
converted into an index called the Southern Oscillation Index (SOI). Usually, there is a
low pressure system in the region of Indonesia and northern Australia, centered near
Darwin. This system brings storminess to the region, providing some parts of Australia,
the driest inhabited continent for sustaining its settlements, wildlife, and ecosystems.
At the same time, there is a high pressure system in the southeastern Pacific, centered
near Tahiti. The sea level pressure at each of these two points is related to each other.
When one is increasing, the other is usually decreasing. Therefore, the difference in sea
level pressure (Tahiti minus Darwin) is used as an index that characterizes ENSO.
Thus, El Niņo is related to the negative phase of SOI and the cold event to the positive
phase. This index, the SOI, has been reliable associated with a number of climate related
events: when the sea level pressure at Darwin increases, the likelihood of drought in the
Australian-Indonesian region also increases; when the pressure at Tahiti decreases, the
likelihood of more rainfall in the equatorial central Pacific region increases. These
particular sea level pressure changes appear to set the stage for a possible onset of El
Nino. Along with pressure changes come changes in wind speed and direction, shifts in the
location of pools of warm and cold oceanic surface water, changes in the strength of
coastal upwelling, and shifts in the location of biological productivity in the ocean
which, in turn, alters the location of various fish populations. It is important to
realize that although there is no one-to-one correlation between observed El Nino events
and the SOI, this relationship is very strong.
Continue to the normal conditions in the Pacific Oceans.
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