El Niņo/La
Niņa
is a naturally occurring 2-7 year
cycle of the ocean-atmosphere system in the Tropical Pacific having important
consequences for weather and climate around the globe.
El Niņo
(Spanish for
the little boy or the
Christ Child) is a disruption of the ocean atmosphere system in the tropical
Pacific. El Nino, an abnormal warming of surface ocean waters in the eastern
tropical Pacific, is one part of what's called the Southern Oscillation. The
Southern Oscillation is the see-saw pattern of reversing surface air pressure
between the eastern and western tropical Pacific; when the surface pressure is
high in the eastern tropical Pacific it is low in the western tropical Pacific,
and vice-versa. Because the ocean warming and pressure reversals are, for the
most part, simultaneous, scientists call this phenomenon the El Nino/Southern
Oscillation or ENSO for short. Normally
trade winds move westward carrying warm water to Australia. Cooler water can
upwell along the South American coast. This cool water carries nutrients that
support large fish populations in the region. Every three to seven years, these
trade winds die and the warm water that was once pushed westward is allowed to
shift back towards South America. South American fisherman have given this
phenomenon the name
El Niņo,
which is Spanish for "The Christ Child," because it comes about the
time of the celebration of the birth of the Christ Child-Christmas.
El Niņo
disrupts the ocean-atmosphere system in the tropical Pacific having
important consequences for weather around the globe. Among these consequences
are increased rainfall across the southern tier of the US and in Peru, which has
caused destructive flooding, and drought in the West Pacific, sometimes
associated with devastating brush fires in Australia.
El
Nino conditions
Precipitation
anomalies during El Niņo in Summer and Winter
La
Niņa (Spanish for the little girl) is essentially the opposite of El Nino The
ocean becomes much cooler than normal. Although, La Niņa is not as well
understood as El
Niņo, it is thought to occur due to an increase in the
strength of the trade winds This increases the amount of cooler water that flows
toward the west coast of South American and reduces water temperatures. Global
climate La Niņa
impacts tend to be opposite those of El
Niņo impacts. In
the tropics, ocean temperature variations in La Niņa
tend to be opposite those of El
Niņo.
La
Nina conditions
Environment
Canada graphics
The
NOAA polar-orbiting satellites (POES) have been collecting sea surface
temperature data for over 22 years. This animation is a compilation of that data
from January 1985 - January 2007. Of note are the changes in the Gulf Stream, El
Nino and La Nina cycles in the Pacific, and the seansonal changes in sea ice
cover.
Normal
Ocean conditions
The images show sea surface
topography from NASA's TOPEX satellite, sea surface temperature's from
NOAA's AVHRR satellite sensor and sea temperature below the surface as
measured by NOAA's network of TAO moored buoys. The three dimensional
relief map shows a sea level rise along the Equator in the eastern Pacific
Ocean of up to 34 centimeters with the red colors indicating an associated
change in sea surface temperature of up to 5.4 degrees Celsius.
El
Nino conditions
The sea temperature below the
surface illustrates how the thermocline (the boundary between warm and
cold sea water at 20 degrees Celcius) is flattened out by El Niņo. These
images are beneath Sea Views of sea surface height (represented by the
bumps) and sea temperature (represented by the color). Red is 30 degrees C
and blue is 8 degrees C. The thermocline is the border between the dark
blue at the bottom and the cyan. The thermocline exists at 20 degrees C.
Data from 1/1/97 to 3/10/98.
La
Nina conditions
General:
During winter El Niņo episodes (top map) feature a strong jet stream and
storm track across the southern part of the United States, and less
storminess and milder-than-average conditions across the North. La Niņa
episodes (bottom map) feature a very wave-like jet stream flow over the
United States and Canada, with colder and stormier than average conditions
across the North, and warmer and less stormy conditions across the South.
Detailed
El Nino: El Niņo episodes are associated with four
prominent changes in the wintertime atmospheric flow across the eastern
North Pacific and North America. The first is an eastward extension and
equatorward shift of the East Asian jet stream from the International Date
Line to the southwestern United States. The second is a more west-to-east
flow of jet stream winds than normal across the United States. The third
is a southward shift of the storm track from the northern to the southern
part of the United States. The fourth is a southward and eastward shift of
the main region of cyclone formation to just west of California. This
shift results in an exceptionally stormy winter and increased
precipitation across California and the southern U.S, and less stormy
conditions across the northern part of the country. Also, there is an
enhanced flow of marine air into western North America, along with a
reduced northerly flow of cold air from Canada to the United States. These
conditions result in a milder than normal winter across the northern
states and western Canada.
Detailed
La Nina: La Niņa episodes are associated with three
prominent changes in the wintertime atmospheric flow across the eastern
North Pacific and North America. The first is an amplification of the
climatological mean wave pattern and increased meridional flow across the
continent and the eastern North Pacific. The second is increased blocking
activity over the high latitudes of the eastern North Pacific. The third
is a highly variable strength of the jet stream over the eastern North
Pacific, with the mean jet position entering North America in the
northwestern United States/ southwestern Canada. Accompanying these
conditions, large portions of central North America experience increased
storminess, increased precipitation, and an increased frequency of
significant cold-air outbreaks, while the southern states experiences less
storminess and precipitation. Also, there tend to be considerable
month-to-month variations in temperature, rainfall and storminess across
central North America during the winter and spring seasons, in response to
the more variable atmospheric circulation throughout the period
During La Niņa
episodes rainfall is enhanced across the western equatorial Pacific, Indonesia
and the Philippines and is nearly absent across the eastern equatorial Pacific.
Elsewhere, wetter than normal conditions tend to be observed during
December-February (DJF) over northern South America and southern Africa, and
during June-August (JJA) over southeastern Australia. Drier than normal
conditions are generally observed along coastal Ecuador, northwestern Peru and
equatorial eastern Africa during DJF, and over southern Brazil and central
Argentina during JJA.
La Niņa episodes also contribute to large-scale temperature departures
throughout the world, with most of the affected regions experiencing abnormally
cool conditions. Some of the most prominent temperature departures
include:
1) below-normal
temperatures during December-February over southeastern Africa, Japan,
southern Alaska and western/central Canada, and southeastern Brazil;
2) cooler than
normal conditions during June-August across India and southeastern Asia,
along the west coast of South America, across the Gulf of Guinea region, and
across northern South America and portions of central America; and
3) warmer than
normal conditions during December-February along the Gulf coast of the
United States.
Data
compiled from The British Antarctic Study, NASA, Environment Canada,
UNEP, EPA and other sources as stated and credited Researched
by Charles Welch-Updated dailyThis Website is a project of the The
Ozone Hole Inc. a 501(c)(3) Nonprofit Organization
