Your search keyword '"Diakhaté, Moussa"' showing total 4 results

1. Changes in the West Africa Monsoon Precipitation Extremes during ENSO developing Phases.

Author

Didi, Sacre Regis, Diakhaté, Moussa, and Diedhiou, Arona

Abstract

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Published

2023

2. Potential Contribution of Climate Conditions on COVID-19 Pandemic Transmission over West and North African Countries.

Author

Diouf, Ibrahima, Sy, Souleymane, Senghor, Habib, Fall, Papa, Diouf, Diarra, Diakhaté, Moussa, Thiaw, Wassila M., and Gaye, Amadou T.

Subjects

COVID-19, COVID-19 pandemic, COMMUNICABLE diseases, HUMIDITY, CLIMATE sensitivity, WATER vapor

Abstract

COVID-19, caused by the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), is a very contagious disease that has killed many people worldwide. According to data from the World Health Organization (WHO), the spread of the disease appears to be slower in Africa. Although several studies have been published on the relationship between meteorological parameters and COVID-19 transmission, the effects of climate conditions on COVID-19 remain largely unexplored and without consensus. However, the transmission of COVID-19 and sensitivity to climate conditions are also not fully understood in Africa. Here, using available epidemiological data over 275 days (i.e., from 1 March to 30 November 2020) taken from the European Center for Disease Prevention and Control of the European Union database and daily data of surface air temperature specific humidity and water vapor from the National Center for Environmental Prediction (NCEP), this paper investigates the potential contribution of climate conditions on COVID-19 transmission over 16 selected countries throughout three climatic regions of Africa (i.e., Sahel, Maghreb, and Gulf of Guinea). The results highlight statistically significant inverse correlations between COVID-19 cases and temperature over the Maghreb and the Gulf of Guinea regions. In contrast, positive correlations are found over the Sahel area, especially in the central part, including Niger and Mali. Correlations with specific humidity and water vapor parameters display significant and positive values over the Sahelian and the Gulf of Guinea countries and negative values over the Maghreb countries. Then, the COVID-19 pandemic transmission is influenced differently across the three climatic regions: (i) cold and dry environmental conditions over the Maghreb; (ii) warm and humid conditions over the Sahel; and (iii) cold and humid conditions over the Gulf of Guinea. In addition, for all three climatic regions, even though the climate impact has been found to be significant, its effect appears to display a secondary role based on the explanatory power variance compared to non-climatic factors assumed to be dominated by socio-economic factors and early strong public health measures. [ABSTRACT FROM AUTHOR]

Published

2022

3. Uncertainties in the Annual Cycle of Rainfall Characteristics over West Africa in CMIP5 Models.

Author

Sow, Magatte, Diakhaté, Moussa, Dixon, Ross D., Guichard, Françoise, Dieng, Diarra, and Gaye, Amadou T.

Subjects

*RAINFALL frequencies, *UNCERTAINTY, *CLIMATOLOGY, *RAINFALL intensity duration frequencies, *METEOROLOGICAL precipitation, *RAINFALL

Abstract

We analyse uncertainties associated with the main features of the annual cycle of West African rainfall (amplitude, timing, duration) in 15 CMIP5 simulations over the Sahelian and Guinean regions with satellite daily precipitation estimates. The annual cycle of indices based on daily rainfall such as the frequency and the intensity of wet days, the consecutive dry (CDD) and wet (CWD) days, the 95th percentile of daily rainfall (R95), have been assessed. Over both regions, satellite datasets provide more consistent results on the annual cycle of monthly precipitation than on higher-frequency rainfall indices, especially over the Guinean region. By contrast, CMIP5 simulations display much higher uncertainties in both the mean precipitation climatology and higher-frequency indices. Over both regions, most of them overestimate the frequency of wet days. Over the Guinean region, the difficulty of models to represent the bimodality of the annual cycle of precipitation involves systematic biases in the frequency of wet days. Likewise, we found strong uncertainties in the simulation of the CWD and the CDD over both areas. Finally, models generally provide too early (late) onset dates over the Sahel (the Guinean region) and overestimate rainfall during the early and late monsoon phases. These errors are strongly coupled with errors in the latitudinal position of the ITCZ and do not compensate at the annual scale or when considering West Africa as a whole. [ABSTRACT FROM AUTHOR]

Published

2020

4. Uncertainties in the Annual Cycle of Rainfall Characteristics over West Africa in CMIP5 Models

Author

Sow, Magatte, Diakhaté, Moussa, Dixon, Ross D., Guichard, Françoise, Dieng, Diarra, and Gaye, Amadou T.

Subjects

CMIP5 models, cessation, 13. Climate action, onset, parasitic diseases, West Africa, rainfall, annual cycle, extremes, uncertainties

Abstract

We analyse uncertainties associated with the main features of the annual cycle of West African rainfall (amplitude, timing, duration) in 15 CMIP5 simulations over the Sahelian and Guinean regions with satellite daily precipitation estimates. The annual cycle of indices based on daily rainfall such as the frequency and the intensity of wet days, the consecutive dry (CDD) and wet (CWD) days, the 95th percentile of daily rainfall (R95), have been assessed. Over both regions, satellite datasets provide more consistent results on the annual cycle of monthly precipitation than on higher-frequency rainfall indices, especially over the Guinean region. By contrast, CMIP5 simulations display much higher uncertainties in both the mean precipitation climatology and higher-frequency indices. Over both regions, most of them overestimate the frequency of wet days. Over the Guinean region, the difficulty of models to represent the bimodality of the annual cycle of precipitation involves systematic biases in the frequency of wet days. Likewise, we found strong uncertainties in the simulation of the CWD and the CDD over both areas. Finally, models generally provide too early (late) onset dates over the Sahel (the Guinean region) and overestimate rainfall during the early and late monsoon phases. These errors are strongly coupled with errors in the latitudinal position of the ITCZ and do not compensate at the annual scale or when considering West Africa as a whole.