17 research outputs found
The possible role of local air pollution in climate change in West Africa
The climate of West Africa is characterized by a sensitive monsoon system that is associated with marked natural precipitation variability. This region has been and is projected to be subject to substantial global and regional-scale changes including greenhouse-gas-induced warming and sea-level rise, land-use and land-cover change, and substantial biomass burning. We argue that more attention should be paid to rapidly increasing air pollution over the explosively growing cities of West Africa, as experiences from other regions suggest that this can alter regional climate through the influences of aerosols on clouds and radiation, and will also affect human health and food security. We need better observations and models to quantify the magnitude and characteristics of these impacts
Potential Impact of 1.5oC and 2oC global warming on consecutive dry and wet days over West Africa
We examine the impact of +1.5 ◦C and +2 ◦C global warming levels above pre-industrial levels on consecutive dry days (CDD) and consecutive wet days (CWD), two key indicators for extreme precipitation and seasonal drought. This is done using climate projections from a multi-model ensemble of 25 regional climate model (RCM) simulations. The RCMs take boundary conditions from ten global climate models (GCMs) under the RCP8.5 scenario.We define CDD as the maximum number of consecutive days with rainfall amount less than 1mm and CWD as the maximum number of consecutive days with rainfall amount more than 1 mm. The differences in model representations of the change in CDD and CWD, at 1.5 ◦C and 2◦C global warming, and based on the control period 1971−2000 are reported. The models agree on a noticeable response to both 1.5 ◦C and 2◦C warming for each index. Enhanced warming results in a reduction in mean
rainfall across the region.More than 80% of ensemble members agree that CDD will increase over the Guinea Coast, in tandem with a projected decrease in CWD at both 1.5 â—¦C and 2â—¦C global warming levels. These projected changes may influence already fragile ecosystems and agriculture in the region, both of which are strongly affected by mean rainfall and the length of wet and dry periods.JRC.E.1-Disaster Risk Managemen
Daily characteristics of West African summer monsoon precipitation in CORDEX simulations
We analyze and intercompare the performance of a set of ten regional climate models (RCMs) along with the ensemble mean of their statistics in simulating daily precipitation characteristics during the West African monsoon (WAM) period (June-July-August-September). The experiments are conducted within the framework of the COordinated Regional Downscaling Experiments for the African domain. We find that the RCMs exhibit substantial differences that are associated with a wide range of estimates of higher-order statistics, such as intensity, frequency, and daily extremes mostly driven by the convective scheme employed. For instance, a number of the RCMs simulate a similar number of wet days compared to observations but greater rainfall intensity, especially in oceanic regions adjacent to the Guinea Highlands because of a larger number of heavy precipitation events. Other models exhibit a higher wet-day frequency but much lower rainfall intensity over West Africa due to the occurrence of less frequent heavy rainfall events. This indicates the existence of large uncertainties related to the simulation of daily rainfall characteristics by the RCMs. The ensemble mean of the indices substantially improves the RCMs' simulated frequency and intensity of precipitation events, moderately outperforms that of the 95th percentile, and provides mixed benefits for the dry and wet spells. Although the ensemble mean improved results cannot be generalized, such an approach produces encouraging results and can help, to some extent, to improve the robustness of the response of the WAM daily precipitation to the anthropogenic greenhouse gas warming
Evaluation and projections of extreme precipitation over southern Africa from two CORDEX models
The study focus on the analysis of extreme precipitation events of the present and future climate over southern Africa.
Parametric and non-parametric approaches are used to identify and analyse these extreme events in data from the
Coordinated Regional Climate Downscaling Experiment (CORDEX) models. The performance of the global climate
model (GCM) forced regional climate model (RCM) simulations shows that the models are able to capture the
observed climatological spatial patterns of the extreme precipitation. It is also shown that the downscaling of the present
climate are able to add value to the performance of GCMs over some areas and depending on the metric used. The
added value over GCMs justify the additional computational effort of RCM simulation for the generation relevant
climate information for regional application. In the climate projections for the end of twenty-first Century (2069-2098)
relative to the reference period (1976-2005), annual total precipitation is projected to decrease while the maximum
number of consecutive dry days increases. Maximum 5-day precipitation amounts and 95th percentile of precipitation
are also projected to increase significantly in the tropical and sub-tropical regions of southern Africa and decrease in the
extra-tropical region. There are indications that rainfall intensity is likely to increase. This does not equate to an
increase in total rainfall, but suggests that when it does rain, the intensity is likely to be greater. These changes are
magnified under the RCP8.5 when compared with the RCP4.5 and are consistent with previous studies based on GCMs
over the region.Water Research Commission-Project K5-2240.http://link.springer.com/journal/105842017-04-30hb2016Geography, Geoinformatics and Meteorolog