How ENSO leads to a cascade of global impacts
ENSO arises from changes across the tropical Pacific Ocean. So why does ENSO affect the climate over sizable portions of the globe, including some regions far removed from the tropical Pacific Ocean? Does the strength of ENSO matter for global impacts?
ENSO affects the sea surface temperature (SST) in regions where fishing is a major industry to some countries. A prominent example is the anchovy fishing routinely done off the northwest coast of Peru. When El Niño occurs, the warmed waters become unfavorable for the fish, which flee for cooler waters, resulting in poor harvests that are detrimental to the Peruvian economy.
But the abnormal tropical Pacfic SSTs are only the beginning of the story of ENSO’s impacts. When El Niño occurs, the central and eastern tropical Pacific Ocean becomes warmer than average. With the elevated SST, there is more thunderstorm activity, or convection, than usual over the waters in the central and eastern tropical Pacific. This convection is caused by the increased temperature and moisture in the air right above the warmed water.
This warm, moist air rises to form thunderstorm clouds. The process causes latent heating in the upper atmosphere: heat from the warmed surface of the ocean is released when water vapor condenses into clouds and rainfall. With more storminess than usual, the upper atmosphere becomes warmer than usual, and this extra heat sets in motion yet another series of important effects.
The Hadley Circulation
The rising air in the tropical Pacific can branch away from the equator toward the higher latitudes, both northward and southward, contributing to the complex circulation patterns that help establish the average worldwide climate features. This poleward movement of air in the upper atmosphere, sinking motion over the subtropics, and the return flow at lower levels of the atmosphere toward the lower pressure at the equator, is called the Hadley circulation (see figure).
When an El Niño causes excess heating in the tropical Pacific upper atmosphere, the air flow toward the poles becomes more vigorous. The change in the strength of the Hadley circulation leads to modifications in the circulation patterns worldwide, including, for example, the position of the jet stream that flows from west to east over the North Pacific in winter months. El Niño tends to lead to an elongated jet stream that can extend all the way to North America and bring an above-average supply of storms across the southern part of the United States.
By strengthening the Hadley circulation, El Niño can trigger a cascade of noticeable departures from the normal rainfall patterns around the globe. The changes in the atmospheric circulation, and subsequent ground-level climate impacts, that stretch across the globe are called El Niño teleconnections (see figure). Teleconnection patterns emerge in climate simulations, and they show up in historical observations.
Observations since 1950 indicate that impacts during El Niño depend on the season. The figure shows what changes, and during which seasons, El Niño is expected to bring about across the globe. It must be emphasized that while these impacts are likely during El Niño, they are not certain to occur. The stronger the El Niño, however, the more likely the teleconnection side effects become. There is also some correlation between the strength of the El Niño and the severity of the effects (Lyon and Barnston, 2005), but, again, it must be stressed that there are no guarantees here either.
The most reliable effects of El Niño are deficient rainfall over Indonesia and northern South America, and excess rainfall in southeastern South America, eastern equatorial Africa, and the southern US.
Lyon, B., and A. G. Barnston, 2005: ENSO and the spatial extent of interannual precipitation extremes in tropical land areas. J. Climate, 18, 5095-5109.
A blog about forecasting El Niño and La Niña.
The ENSO blog is written, edited, and moderated by Michelle L’Heureux (NOAA CPC), Emily Becker and Tom DiLiberto (contractors to CPC), Anthony Barnston (IRI), and Rebecca Lindsey (contractor to NOAA CPO). Posts reflect the views of the bloggers themselves and not necessarily Climate.gov, NOAA, or Columbia University/IRI.