The potential of increasing man-made air pollution to reduce rainfall over southern West Africa

Pante, Gregor; Knippertz, Peter; Fink, Andreas H.; Kniffka, Anke

doi:10.5194/acp-21-35-2021

Cited by 8 publications

(9 citation statements)

References 70 publications

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“…Furthermore, the reduction of precipitation in southern West Africa due to the anthropogenic aerosol emitted along the coast, changes the liquid water transported towards the Sahel, and modifies the winds and soil humidity, and as a consequence dust emissions, as shown by Menut et al (2019). The present study adds evidence to the emerging hypothesis that, during the West African monsoon, increasing anthropogenic aerosol pollution in southern West Africa has already caused a precipitation reduction (Pante et al, 2021).…”

Section: Discussionsupporting

confidence: 64%

Sensitivity of low-level clouds and precipitation to anthropogenic aerosol emission in southern West Africa: a DACCIWA case study

et al. 2022

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Abstract. During the West African summer monsoon, pollutants emitted in urbanized coastal areas modify cloud cover and precipitation patterns. The Dynamics-Aerosol-Chemistry-Cloud Interactions in West Africa (DACCIWA) field campaign provided numerous aircraft-based and ground-based observations, which are used here to evaluate two experiments made with the coupled WRF–CHIMERE model, integrating both the direct and indirect aerosol effect on meteorology. During one well-documented week (1–7 July 2016), the impacts of anthropogenic aerosols on the diurnal cycle of low-level clouds and precipitation are analyzed in detail using high and moderate intensity of anthropogenic emissions in the experiments. Over the continent and close to major anthropogenic emission sources, the breakup time of low-level clouds is delayed by 1 hour, and the daily precipitation rate decreased by 7.5 % with the enhanced anthropogenic emission experiment (with high aerosol load). Despite the small modifications on daily average of low-level cloud cover (+2.6 %) with high aerosol load compared to moderate, there is an increase by more than 20 % from 14:00 to 22:00 UTC on hourly average. Moreover, modifications of the modeled low-level cloud and precipitation rate occur far from the major anthropogenic emission sources, to the south over the ocean and to the north up to 11∘ N. The present study adds evidence to recent findings that enhanced pollution levels in West Africa may reduce precipitation.

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Section: Discussionsupporting

confidence: 64%

Sensitivity of low-level clouds and precipitation to anthropogenic aerosol emission in southern West Africa: a DACCIWA case study

et al. 2022

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“…In both studies, atmospheric heating (BBA solar absorption) and SST anomalies (BBA surface dimming and cloud adjustments) are identified as key processes intrinsically linked to absorbing properties of smoke. These recent (25,26) results underline that insufficient absorption by smoke over the tropical ocean in global models would limit these interactions between BBA and the fast responses of precipitation (drying) over the southern West Africa. In addition, even if the SSA bias appears to be less pronounced over the African continent, the drying effect of absorbing smoke over central Africa (24) would not be fully represented for CMIP6 models with too scattering BBA over the continent (Fig.…”

Section: Discussionmentioning

confidence: 96%

“…We argue that the underrepresentation of BBAinduced heating in GCMs would lead to insufficient increases in low-level stratocumulus clouds, which are known to be extremely important for the radiation/climatic balance (22). Our findings make it difficult to have confidence in other fast responses linked to BBA solar absorption, such as precipitation feedbacks (34) over the tropics during the biomass-burning season including the drying effect of BBA recently highlighted by (25,26) over the densely populated southern West African region.…”

Section: Introductionmentioning

confidence: 83%

Climate models generally underrepresent the warming by Central Africa biomass-burning aerosols over the Southeast Atlantic

et al. 2021

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The radiative budget, cloud properties, and precipitation over tropical Africa are influenced by solar absorption by biomass-burning aerosols (BBA) from Central Africa. Recent field campaigns, reinforced by new remote-sensing and aerosol climatology datasets, have highlighted the absorbing nature of the elevated BBA layers over the South-East Atlantic (SEA), indicating that the absorption could be stronger than previously thought. We show that most of the latest generation of general circulation models (GCMs) from the sixth phase of the Coupled Model Intercomparison Project 6 (CMIP6) underestimates the absorption of BBA over the SEA. This underlines why many (~75%) CMIP6 models do not fully capture the intense positive (warming) direct radiative forcing at the top of the atmosphere observed over this region. In addition, underestimating the magnitude of the BBA-induced solar heating could lead to misrepresentations of the low-level cloud responses and fast precipitation feedbacks that are induced by BBA in tropical regions.

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“…The little dry season coincides with the peak of the West African monsoon, which brings heavy rain further north in West Africa. Interannual variability in rainfall is strongly influenced by sea surface temperatures (SSTs) in the Tropical Atlantic ( 25 ). In contrast to Amazonia, most of the rain comes from mesoscale convective systems (MCSs; ref.…”

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confidence: 99%

“…Positive trends are also evident for extreme, daily rainfall totals in gauge-based, regional analyses over SWA ( 30 , 31 ). At the same time, there is a negative trend in total SWA rainfall in the little dry and second rainy seasons, which may be linked to rainfall suppression by anthropogenic aerosols ( 25 ). Here, however, we focus on spatial variations in the trends of convective systems on subregional scales and their links to local deforestation.…”

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confidence: 99%

“Late-stage” deforestation enhances storm trends in coastal West Africa

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Parker

et al. 2022

Proc. Natl. Acad. Sci. U.S.A.

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Deforestation affects local and regional hydroclimate through changes in heating and moistening of the atmosphere. In the tropics, deforestation leads to warming, but its impact on rainfall is more complex, as it depends on spatial scale and synoptic forcing. Most studies have focused on Amazonia, highlighting that forest edges locally enhance convective rainfall, whereas rainfall decreases over drier, more extensive, deforested regions. Here, we examine Southern West Africa (SWA), an example of “late-stage” deforestation, ongoing since 1900 within a 300-km coastal belt. From three decades of satellite data, we demonstrate that the upward trend in convective activity is strongly modulated by deforestation patterns. The frequency of afternoon storms is enhanced over and downstream of deforested patches on length scales from 16 to 196 km, with greater increases for larger patches. The results are consistent with the triggering of storms by mesoscale circulations due to landscape heterogeneity. Near the coast, where sea breeze convection dominates the diurnal cycle, storm frequency has doubled in deforested areas, attributable to enhanced land–sea thermal contrast. These areas include fast-growing cities such as Freetown and Monrovia, where enhanced storm frequency coincides with high vulnerability to flash flooding. The proximity of the ocean likely explains why ongoing deforestation across SWA continues to increase storminess, as it favors the impact of mesoscale dynamics over moisture availability. The coastal location of deforestation in SWA is typical of many tropical deforestation hotspots, and the processes highlighted here are likely to be of wider global relevance.

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The potential of increasing man-made air pollution to reduce rainfall over southern West Africa

Cited by 8 publications

References 70 publications

Sensitivity of low-level clouds and precipitation to anthropogenic aerosol emission in southern West Africa: a DACCIWA case study

Sensitivity of low-level clouds and precipitation to anthropogenic aerosol emission in southern West Africa: a DACCIWA case study

Climate models generally underrepresent the warming by Central Africa biomass-burning aerosols over the Southeast Atlantic

“Late-stage” deforestation enhances storm trends in coastal West Africa

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