Climate Outlook
AFRICA August 2002 - January 2003
Issued: July 2002
The IRI has prepared this experimental Climate Outlook for Africa for
August 2002 - January 2003.
Of relevance in the preparation of this outlook is the
prediction of warmer than average conditions in the
equatorial Pacific for the next 6 to 9 months.
Currently the sea surface temperatures (SSTs) across
much of the eastern and central equatorial Pacific are more
than 0.5 degrees C warmer than their long-term average
(SSTs),
particularly in the central part of the basin.
Weakly warm equatorial Pacific SST conditions
(near or slightly higher than 0.5 C) are in effect for the first seasons
of the forecast,
August-October 2002,
September-November 2002.
The central equatorial Pacific, near the dateline, is
currently observed to be warmer (SSTs over
1 degree C above normal) than these predictions, and this discrepancy
has been considered in developing the climate forecasts. The predictions
maintain weak El Nino conditions (SSTs between 0.5
and 1 degree C above normal) throughout the forecast period, increasing
slightly in the last season November-January 2003.
Note that this prediction for a weak
El Nino is a prediction given by a particular ENSO prediction model. It is
described here because it served as the boundary forcing for the
following climate forecast, which is primarily based on dynamical
global climate models. This should not be confused with the
IRI's ENSO Statement
September-November 2002, which while indicating an high likelihood
for an El Nino to continue through 2002, also highlights the uncertainty
present in the prediction, including the predicted
strength of the possible El Nino.
In the other tropical oceans, warmer than average SSTs continue to
dominate much of the Indian Ocean, and are not expected to decrease as
rapidly as suggested by the SST predictions. However, the actual
long-term evolution of the Indian Ocean SSTs is difficult to foresee
at this time. The area of above-average temperature in the tropical
south Atlantic Ocean (near the coast of Africa) is expected to persist through
at least the first half of the forecast period.
METHODS -
This Outlook was prepared using the following
procedures and information:
A) Coupled ocean-atmosphere model predictions of tropical Pacific SST
covering the forecast period. Particularly heavy weighting has been
given to predictions from the coupled model operated by the NOAA
National Centers for Environmental Prediction, Climate Modeling Branch.
This model suggests a continuation of near-average conditions during the
first forecast season. The forecast for near-neutral conditions is
consistent with some, but not all, numerical and statistical forecasts
of central and eastern Pacific SSTs.
B) Forecasts of the tropical Indian ocean using a statistical model
developed by the IRI.
C) Global atmospheric general circulation model (GCM) predictions of the
atmospheric response to the present and predicted sea-surface
temperature patterns.
D) Other sources of information include
NASA's
Seasonal to Interannual Prediction Project (GSFC-NASA)
and also seasonal prediction research at COLA.
The procedures, models, and data used to derive this Climate Outlook may
be somewhat different from those used by the national meteorological
services in the region. Thus, this product may differ from the official
forecasts issued in those areas. The Climate Outlook for
August 2002 - January 2003
is dependent on the accuracy of the SST predictions. For the
tropical Pacific, these predictions can be expected to provide useful
information, but there is some uncertainty concerning the evolution of
SSTs. Spread (variation) in global SST predictions is a source of
uncertainty in the Outlook provided here. In particular, the forecasts
for the tropical Indian and Atlantic oceans have been an important
influence on the forecasts over Africa. Note that even if perfectly
accurate SST forecasts were possible, there would still be uncertainty
in the climate forecast due to chaotic internal variability of the
atmosphere. These uncertainties are reflected in the probabilities given
in the forecast.
It is stressed that the current status of seasonal-to-interannual
climate forecasting allows prediction of spatial and temporal averages,
and does not fully account for all factors that influence regional and
national climate variability. This Outlook is relevant only to seasonal
time scales and relatively large areas; local variations should be
expected, and variations within the 3-month period should also be
expected. For further information concerning this and other guidance
products, users are strongly advised to contact their National
Meteorological Services.
OUTLOOK -
This Outlook covers four seasons: August-Octover 2002,
September-November 2002, October-December 2002 and November-January 2003.
Maps are given showing tercile probabilities of
precipitation and temperature. The maps for precipitation indicate the
probabilities that the seasonal precipitation will fall into the wettest
third of the years (top number), the middle third of the years (middle
number), or the driest third of the years (bottom number). The color
shading indicates the probability of the most dominant tercile -- that
is, the tercile having the highest forecast probability. The color bar
alongside the map defines these dominant tercile probability levels. The
upper side of the color bar shows the colors used for increasingly
strong probabilities when the dominant tercile is the above-normal
tercile, while the lower side shows likewise for the below-normal
tercile. The gray color indicates an enhanced probability for the
near-normal tercile (nearly always limited to 40%). As before, numbers
and their associated histograms show the probabilities of the three
terciles. In areas with lots of spatial detail, there may not be
sufficient room on the map, to allow histograms for each region. In
those cases, some idea of the probabilities may be gained from the color
alone. A qualitative outlook of climatology ("C") indicates that there
is no basis for favoring any particular category.
Areas that are marked by "D" represent regions for which less than 3cm of
precipitation typically occurs over the season.
Otherwise, for example, in the case of
most of Sudan in August-Octover 2002
(Map A),
there is a 25% probability that the precipitation will be in the
wettest third of the years, a 35% chance it will be in the near-normal
third of the years, and a 40% chance that the precipitation will be in
the driest third of the years.
Maps of temperature show expected probabilities that the seasonal
temperatures will fall into the warmest third of the years, the middle
third of the years, or the coldest third of the years
(Map A).
The numbers for each region on the temperature maps
indicate the probabilities of temperatures to fall in each of the three
categories, above-, near-, and below-normal.
An
additional precipitation map
is provided for the first season indicating probabilities for extreme
precipitation anomalies. Extremes are defined as anomalies that fall
within the top and bottom 15th percentile of the observed records. A
priori, there is a 15% probability of being within the extremely wet
category, and a 15% probability of being within the extremely dry
category, leaving a 70% probability that the precipitation will not be
extreme. The maps indicate areas of increased risk of extreme
precipitation totals. Three levels of increased risk are defined:
slightly enhanced risk, enhanced risk, and greatly enhanced risk. For
slightly enhanced risk, there is a 25-40% probability that precipitation
will be within the indicated extreme, i.e. wet or dry. This represents
an approximate doubling of the climatological risk. For enhanced risk,
there is a 40-50% probability that precipitation will be within the
indicated extreme. This represents an approximate tripling of the
climatological risk. For greatly enhanced risk, the probability that
precipitation will be within the indicated extreme exceeds 50%, i.e. the
indicated extreme is the most likely outcome. A similar map is provided
in the first season indicating probabilities of
extreme temperature
anomalies.
Boundaries between sub-regions should be considered as transition zones,
and their location considered to be only qualitatively correct.
August-Octover 2002 through November-January 2003:
The following discussion briefly describes the probability anomaly forecasts:
Precipitation
Enhanced probabilities for above normal precipitation are forecast
for portions of the Guinea Coast and the coast of Cameroon through Gabon,
for all four forecast periods. In tropical eastern Africa, enhanced probabilities
for below normal precipitation for the first two forecast periods is replaced
by above normal precipitation for the last two periods, in association with
a expected weak to moderate El Nino.
Temperature
Enhanced probability for above normal temperature is forecast
for most of the African continent for all four forecast periods, with greatest
confidence for warth for the first and second periods.
OBSERVED CLIMATOLOGY DATA for Aug-Sep-Oct,
Sep-Oct-Nov, Oct-Nov-Dec and Nov-Dec-Jan
CLIMATOLOGICAL AVERAGE:
TERCILE THRESHOLDS (33%-ile & 67%-ile):
EXTREME THRESHOLDS (15%-ile & 85 %-ile):
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