Using high resolution, color-sensitive images from U.S. and Japanese satellites, Mati Kahru and Greg Mitchell report in the September 15 issue of Geophysical Research Letters that the 1997-1998 event--one of the strongest El Niņos on record-- supplanted the normal upwelling of cold, nutrient-rich waters in the California Current System.

"When El Niņo suppresses the availability of nutrients in the sunlit surface waters, the abundance of phytoplankton declines," said Greg Mitchell, research biologist in the Marine Research Division at Scripps. "Phytoplankton communities are the primary producers for the ocean, comparable to grasslands for terrestrial systems. Success of fish population recruitment, and therefore commercial fisheries, may in part depend on interannual cycles of nutrient and phytoplankton distributions associated with El Niņo and La Niņa."

The authors argue that one of El Niņo's effects on the California Current System is both a reduction and a more uniform distribution of phytoplankton, which results in a critical reduction in the high-concentration patches of phytoplankton that may be necessary for success in the planktonic stages of fish populations.

While Kahru and Mitchell documented reductions in satellite estimates of surface phytoplankton for water off central and southern California, they found a significant increase off Baja California. "These moderate abundances of phytoplankton extended far off shore in warm waters, which had not been observed before," said Mitchell. "We believe this increase off Baja may be due to blooms of 'nitrogen-fixing' cyanobacteria. Some open ocean cyanobacteria are more abundant in nutrient-depleted, strongly stratified waters because they are capable of fixing nitrogen gas into organic matter, reducing their dependence on nutrient upwelling."

Kahru and Mitchell's data showed the effects that made the 1997-1998 event one of the strongest on record. In a 15-year span, satellite sea surface temperatures for some regions were the highest in 1998 and lowest in 1999. The researchers observed a strong transition out of the El Niņo in 1998 into the cold surface water La Niņa event in 1999.

"The difference between '98 and '99 in satellite-derived temperature was the most dramatic that's been observed, " said Kahru.

Kahru, Mitchell and their colleagues specialize in ocean observations combined from satellites and ships. They develop mathematical relationships to interpret satellite data, using imagery from the Ocean Color and Temperature Sensor (OCTS), the Sea-viewing Wide Field-of-view Sensor (SeaWiFS), and the Coastal Zone Color Scanner (CZCS). Funding for Kahru and Mitchell's study was provided by NASA.

This paper will appear in Geophysical Research Letters, vol. 27, no. 18 (September 15, 2000).

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