The current study is conducted over West Africa, which is located over the domain 5–20∘ N, 15∘ W–10∘ E, and spans the Atlantic coast to Chad and the Gulf of Guinea to the southern fringes of the Sahara (Fig. ). The climate in West Africa is mostly influenced by the West African monsoon flux, which governs the rainy season and thus the rain-fed agriculture. The West Africa region has a semi-arid and hot climate with a dry season (Köppen classification BSh or BWh). This climate corresponds to an alternation between a short wet season and a very long dry season. The West Africa region shows high climate variability at a regional and local scale. In this study, we are interested in the coastal and continental parts of West Africa. We have therefore identified three regions based on their location and climate variability on which we have conducted our analyses. The choice of these regions is coherent with , who used a hierarchical-clustering approach to define some city blocks over West Africa. The 15 cities investigated here were classified into the three following regions:

continental zone (CONT hereafter) including the cities of Bamako, Ouagadougou and Niamey (Fig. );

The CONT and GU regions are very similar to the clusters found by (see figure under the title “Clusters membership” in ). The ATL region is a specific case because not all cities belonging to the region are present in the clusters defined by . Therefore, we analysed the spatial variability of heat wave characteristics for each city. In this way, we found a consistent pattern across cities (see Fig. S1 in the Supplement for maximum T2m values using the 90th percentile as a threshold), and we grouped them to form the ATL block.

Reanalysis products are often taken as an alternative solution to observational weather and climate data due to availability and accessibility problems, particularly in data-sparse regions such as Africa . In this work, to access information with a regular spatial grid and a large horizontal coverage, we used two state-of-the-art reanalysis products: the fifth-generation European Centre for Medium-Range Weather Forecasts (ECMWF) reanalysis (ERA5; ) and the Modern-Era Retrospective analysis for Research and Applications, version 2 (MERRA-2; ), from the National Oceanic Atmospheric Administration (NOAA) (in the following, we will use “MERRA” to refer to MERRA-2). ERA5 reanalysis has a native spatial resolution of 0.28125∘ (∼31 km) with 137 hybrid sigma–pressure levels from the surface up to 80 km, yet downloaded data are interpolated to a regular latitude–longitude grid of 0.25∘×0.25∘. ERA5 is produced using 4D-Var data assimilation and the Cycle 41r2 (Cy41r2) of the ECMWF Integrated Forecasting System (IFS), which was operational in 2016. MERRA reanalysis has a spatial resolution of 0.625∘×0.5∘ with 42 standard pressure levels. MERRA uses an upgraded version of the Goddard Earth Observing System model version 5 (GEOS-5) data assimilation system and the Gridpoint Statistical Interpolation (GSI) analysis scheme of . MERRA is produced using a 3D-Var data assimilation algorithm. These two reanalyses datasets can be accessed through the Climserv database from the Institut Pierre-Simon Laplace (IPSL) server. To be consistent in our analyses, we transformed the spatial resolution of MERRA from 0.625∘×0.5∘ to 0.25∘×0.25∘ to match the one of ERA5; this is done using a first-order conservative interpolation. We use hourly data covering the period from 1 January 1993 to 31 December 2020 for both ERA5 and MERRA. Our choice of ERA5 and MERRA to conduct this study is supported by some previous work showing that these two reanalyses included among the most relevant used in African regions e.g.. As the main objective here is to process heat wave detection, we focus on atmospheric variables at the surface such as 2 m temperature (T2m), 2 m relative humidity (RH), 2 m dewpoint temperature, 2 m specific humidity, 10 m wind components, and water vapour pressure (e) from which wet-bulb temperature (Tw) and apparent temperature (AT; ) were derived. These atmospheric variables have a significant impact on human thermal comfort . Daily minimum and maximum values were calculated for T2m, Tw, AT and the universal thermal comfort index (UTCI; ). AT is similar to the heat index developed by . The climate variables e, Tw, AT and RH were calculated using the following formulas: 1e=6.1121⋅exp⁡17.502⋅T240.97+T ,

2Tw=T⋅atanA(RH+B)12+atan(T+RH)-atan(RH-C)+D⋅(RH)32⋅(atan(E⋅RH))-F (RH is given as a percentage, for example 32 for RH =32 %), 3AT=T+0.33×10-0.70⋅Ws-4.00 .

RH is computed differently based on the variables available in the products. The first formula is used to compute RH in ERA5, and the second is used for MERRA. 4RH=100⋅exp⁡a⋅Tdb+Tdexp⁡a⋅Tb+T , 5RH=0.263⋅p⋅q⋅exp⁡(17.67⋅(T-T0)T-29.65)-1 (https://earthscience.stackexchange.com/questions/2360/how-do-i-convert-specific-humidity-to-relative-humidity, last access: 3 April 2023), where a=17.625, b=243.04, A=0.151977, B=8.313659, C=1.676331, D=0.00391838, E=0.023101, F=4.686035 and T0=273.16 K. T (∘C), Td (∘C), T0 (K), p (hPa), Ws (m s-1) and q are the ambient temperature, dewpoint temperature, reference temperature, pressure, wind speed and specific humidity respectively.

The land sea mask dataset used in this work was derived from ERA5 reanalysis; it can be accessed on the Copernicus Climate Data Store (CDS). T2m daily maximum and minimum observations at Dakar–Yoff station in Senegal and Aéroport Félix Houphouët-Boigny (FHB) station in Côte d'Ivoire were used to evaluate our interpolation method. This is due to the fact that we do not have access to other station data in these regions. The data from Dakar–Yoff extend from 1 January 1973 to 31 December 2018 and contain almost 16 % missing values, and the data from Aéroport FHB extend from 1 January 2005 to 31 December 2017 and contain 0.35 % missing values. These data were provided by colleagues from the Agence Nationale de l'Aviation Civile et de la Météorologie (ANACIM) for the Dakar–Yoff station and from the Institut des Géosciences de l'Environnement (IGE) for the Aéroport FHB station.

The first step of this work consists in assessing the evolution of T2m in the ERA5 and MERRA reanalyses. The climatological state (annual mean) of T2m in ERA5 and MERRA has been evaluated over the West Africa region from 1 January 1993 to 31 December 2020 (Fig. a–b). Both reanalyses show very similar climatologies of T2m: a north–south gradient of the temperature. The Sahel region appears to be warmer than the Guinean region; this is because of the advection of cold air coming from the Atlantic Ocean to the Guinea coast. This fresh air tends to cool down temperatures in this region. The bias between ERA5 and MERRA is computed using ERA5 as reference (Fig. c). MERRA shows a cold bias with respect to ERA5 over the Sahel region and Guinean zone except in some countries (e.g. Guinea-Bissau, Sierra Leone, Liberia) where we observe a hot bias. The biases between ERA5 and MERRA are around ±2 ∘C. The bias highlighted between ERA5 and MERRA is very significant for heat wave detection. Thereafter, we evaluated the temporal consistency between the two reanalyses by computing the ACC for T2m, AT and Tw (see Fig. d–i). We observed a weak correlation over the south of the Sahel and Guinean region of around 0.5 (0.7) for maximum (minimum) values of T2m and AT (see Fig. d–e and g–h). This could be explained by the presence of a strong diurnal cycle in the region associated with high variability during the day and less variability during the night. This will lead to high variability in the daily maximum values compared to the daily minimum values. Tw shows a uniform repartition of correlation between ERA5 and MERRA of around 0.85 except in the Guinean region with maximum values. Good agreement between the two products is found with Tw. We can infer from this result that Tw has a more stable signal than T2m and AT. Knowing that heat waves are defined as extreme events, it is important to evaluate the consistency of the reanalysis products for the representation of extreme values. The hit rate and GSS were calculated in terms of hot days using T2m, and we noticed very low values between the two reanalysis products over the southern Sahel and Guinean region of around 0.25 (see Fig. S4). Similar results have been found with Tw (not shown). The lack of coherence between ERA5 and MERRA on the representation of hot days would result in discrepancies in the number of heat wave events derived from the two reanalyses. The analysis of heat wave frequency in the two products using T2m and AT shows big differences over the coastal region (see Fig. S5). This is very consistent with the ACC results shown earlier. These discrepancies in the ERA5 and MERRA reanalyses in West Africa were also highlighted by . The potential origins of these differences are explored in Sect. 4. The spatial variability of heat wave occurrence in ERA5, using T2m and AT as indicators, is very similar regardless of the methods applied for heat wave detection. This strong correlation between T2m and AT is also observed when using MERRA reanalysis (see Fig. S6). Even if the reanalyses show discrepancies over the south of the Sahel and coastal region with respect to key variables, the correlation between the variables is preserved.

As discussed earlier in Sect 2.3.2, “Heat wave detection”, the threshold value used for heat wave monitoring has a significant impact on heat wave characteristics. The threshold value is generally tailored to the application that is to be carried out. In this part of the work, we investigate the sensitivity of heat wave frequency to different thresholds. To achieve this goal, we define four relative threshold values calculated over the entire period: the 75th, 80th, 85th and 90th daily percentiles. The choice of these thresholds for assessing changes in heat wave characteristics is based on previous work. Many studies use the 90th percentile to define a heat wave e.g.; other studies use the 75th percentile . Based on these studies, we decided to test the sensitivity of threshold values from the third quartile (75th percentile) to the 90th percentile by steps of 5 % to quantify significant changes in heat wave frequency. As we are studying extreme events, it is not relevant to go below the third quartile; knowing also that this study focuses on human impacts of heat waves, the 90th percentile is enough as a maximum threshold. Heat wave detection is treated separately for these four thresholds (see Fig. S7). The sensitivity of heat wave frequency or duration with respect to the thresholds (75th, 80th, 85th, 90th percentiles) is treated independently for the four thresholds; this is done by calculating the linear evolution coefficient over each grid point. The linear evolution coefficient is defined as the slope of the linear regression line fitted between the threshold values (Q75, Q80, Q85, Q90) and the number of events associated with each threshold (NQ75, NQ80, NQ85, NQ90) or their corresponding duration (DQ75, DQ80, DQ85, DQ90). The calculation of the linear evolution coefficient is carried out according to the following steps:

After processing for heat wave detection at each grid point for the four thresholds separately, we compute for each of them the frequency and duration of heat waves.

We are aware that this regression based on four points is not very robust; nevertheless it makes it possible to obtain information on the evolution of the heat wave characteristics with respect to the thresholds. We therefore assessed the significance of the slope values with respect to the thresholds using a confidence level of 95 %. The significance of the slope was evaluated using a two-sided chi-squared statistics test .

The linear evolution is given by the following equations: 13N=aw⋅threshold+bw,14D=aw′⋅threshold+bw′, where aw, aw′ and bw, bw′ are the slopes and intercepts of the regressions at the grid point w for heat wave frequency and duration respectively.

This analysis is conducted with T2m and Tw extracted from MERRA and ERA5 reanalyses. We find a high spatial variability in the sensitivity of heat wave occurrence to the threshold values over West African regions (Figs. S8 and S9). Some regions are more sensitive than others; this can be explained by a strong seasonal cycle of the T2m and Tw signals in those regions. We observe small changes in the frequency and duration of heat waves with respect to the thresholds when using the minimum and maximum values of T2m or Tw (Figs. S8c, f, c, f and S9c, f); this is related to the small sample size of events detected with method 3 (see Sect. 2.3.2 for more details). As the results show, the frequency of heat waves can be expected to increase with decreasing threshold values (see Figs. S8 and S7). Heat waves detected using low threshold values are very persistent and last for several days (Fig.  shows an illustration with T2m used as an indicator). This can be explained by the fact that when using a low threshold value, one can expect to have many days with temperature values above the daily threshold. Conversely, for heat waves detected with high threshold values, the duration of the events is considerably reduced. This is statistically coherent because the number of consecutive days with temperature above the threshold will decrease as the threshold increases. In general, we find that the duration of heat waves is more sensitive to the threshold values than their frequency. This is very coherent because the persistence of a heat wave will be mainly affected by the threshold values used for the detection.

We have shown that the heat wave detection is very sensitive to threshold values. Based on the literature review and the application of this work, for the rest of the study, we use the 90th percentile for heat wave analyses e.g. using ERA5 reanalysis (Fig. ). We identified four indicators – T2m, Tw, AT and UTCI – from which heat wave detection was processed using three different methods (see Sect. 2.3 for more details). We notice that the occurrences of daytime and nighttime heat waves (Fig. a–d, e–h) are in the same range of values, while for concomitant events (Fig. i–l), the occurrence of heat waves is drastically reduced by 14. This could be explained by the facts that nighttime and daytime heat waves do not necessarily occur at the same time and their origins are totally different. Daytime heat waves will be mainly influenced by incoming solar radiation, while nighttime heat waves will be mainly influenced by the water vapour content of the air mass . We observe a high occurrence of nighttime heat waves over the coastal region from Guinea to Cameroon (Fig. a–d) linked to moist air coming from the Atlantic Ocean in the region during the night; daytime heat waves are more frequent in the Sahel and north-east of the Sahara (Fig. e–h) due to hot temperatures over the continental regions. When analysing nighttime heat wave events from each indicator (Fig. a–d), it appears that Tw heat waves are more frequent than T2m/AT/UTCI events. It seems that Tw is more sensitive to humidity than the other indicators (see formula of Tw); this could explain the high frequency of events observed during the night in the coastal region. Regarding daytime heat waves (Fig. e–h), the spatial variability of events is more consistent for all the indicators in the Sahelian zone. However, some differences are observed: an increase in heat wave occurrence over the coastal region with Tw is noticed compared to T2m, AT and UTCI. The detection of heat wave events with method 3 shows that Tw events are more frequent than T2m/AT/UTCI events with a maximum of occurrence located over the northern Sahel. This means that daytime and nighttime heat waves occur frequently and simultaneously over the Sahel with Tw. From this result, we can deduce that humidity plays a major role in the occurrence of concomitant heat waves, which are very dangerous for human health. In this section, we show the high sensitivity of heat wave detection to the methodology applied and to the variables used as indicators. The role of humidity in heat wave occurrence in the coastal region has also been highlighted. Similar results are found with MERRA reanalysis (not shown).

In summary, the heat wave detection is influenced by many parameters: the dataset, threshold values, indicators and methodology used to define such an event. There is a high dependency between these parameters and the climatic region investigated. We illustrate the sensitivity of heat wave characteristics to the previous parameters in the CONT region (Fig. ), as well as the ATL and GU regions (see Figs. S10 and S11) using ERA5 and MERRA reanalyses.

In this section, we analyse the spatial variability of heat waves in three climate regions (CONT, ATL and GU; see the “Region of interest” section for more details) using T2m, AT and Tw as indicators and reanalysis data. Although ERA5 is slightly better than MERRA when compared to station data (Fig. S3b), we have evaluated the recent evolution of heat waves in both reanalyses. To do so, we firstly assessed the interannual variability of heat waves and their characteristics from 1993 to 2020. For each region, the characteristics of heat waves were calculated as the ratio of the sum of the characteristics of all the cities belonging to a region divided by the number of cities. We identified some particularly hot years with a high frequency of nighttime, daytime and concomitant heat waves: 1998, 2005, 2010, 2016, 2019 and 2020 in the three regions for all the indicators (see Figs. , S12 and S13). These peak heat wave years are addressed in Sect. 4. The GU region appears to have experienced more heat waves over the last decade than the CONT and ATL regions (see Fig. S12 for daytime events and Fig. S13 for nighttime). The mean duration of heat waves detected in the three regions is in the same range of values with some specific persistent events at the end of the period in the ATL and GU regions (not shown). Stronger and more persistent heat waves are found in the CONT region. From a statistical point of view, this is due to less variability in the signal of indicators in the region, which favours the detection of consecutive days with indicator values above the threshold. The highest occurrences of heat waves in the three regions are associated with Tw for daytime and nighttime events (see Figs. S12 and S13 respectively). Conversely, high-intensity heat waves are associated with AT (not shown) in the three regions. We can infer from this result that AT presents a more stable signal in the regions compared to T2m and Tw. Concomitant high-intensity events are found in the CONT and ATL regions (see Fig. S15).

We also investigate the seasonal distribution of heat wave occurrence in the three regions. We find an increase in the frequency of daytime and nighttime heat waves at the beginning of the season and during the retreat period of the West Africa monsoon (starting in September; see Fig. S14a–c). A decrease in heat wave frequency is observed during the active phase of the monsoon in the three regions; this is consistent because the monsoon flow brings rainfall into the region, resulting in a cooling effect. The concomitant heat waves show a seasonal cycle with strong fluctuations (Fig. S16). This is due to the fact that concomitant events are conditioned by daytime and nighttime heat waves, which are two distinct processes.

The seasonal cycle of the duration and intensity of heat waves follows the same distribution as the heat wave occurrence (see Fig. a–c and d–f respectively). Persistent and strong-intensity heat waves (nighttime, daytime) occur at the beginning and the end of the season, while short-duration and low-intensity events occur during the monsoon phase (Fig. a–c, d–f). This is verified for all the three indicators despite some discrepancies. The period 1993–2020 is then divided into 3 decades – 1993–2001, 2002–2011 and 2012–2020 – and we evaluate the contribution of each decade to the heat wave characteristics over the whole period (see Fig.  for heat wave duration). Results are similar when analysing the intensity of heat waves (not shown). The percentiles used for the detection of heat waves in each decade are computed over the whole period 1993–2020. It is clearly shown with ERA5 that the major contribution to heat wave characteristics over the period comes from the last decade (Fig. g–i). We notice a progressive increase in frequency, duration and intensity of all the heat waves (daytime, nighttime and concomitant) from the first to the last decade in the three regions (see Figs. S14j–l and S16j–l); this is true for all the indicators. Using ERA5 reanalysis, we found the last decade (2012–2020) shows a major contribution to around 50 % of heat wave characteristics over the period 1993–2010, while the first and second decades contribute up to 22.4 % and 27.6 % respectively. This contribution of the last decade over the total period is not effective in MERRA reanalysis, where the different decades appear to have a similar contribution. This is the result of the uncertainties highlighted earlier in both reanalyses. The reinforcement of extreme events such as heat waves during the last decade in ERA5 is possibly linked to global warming. This result is consistent with other studies that show an increase in heat wave frequency and characteristics under climate change e.g.. When analysing the severity of heat waves over the previous 3 decades using the mean duration and intensity (see Fig. S17 and S18), we do not find a significant increase in heat wave characteristics.

After the evaluation of the temporal evolution of heat waves over the three regions, we analyse their persistence based on their duration using ERA5 and MERRA reanalyses and maximum values of the indicators (see Figs.  and S19 respectively). We defined five types of event as described in Table . We observed that approximately 75 % of daytime heat waves have a duration of 3–6 d with at least 40 % of events belonging to C1 (Fig. ). Very persistent daytime heat waves contribute to at least 9 %–13 % of the events registered. Severe and very severe daytime events are extremely rare in the region, and they contribute up to 12 % of the total number of heat waves. The classification is not too sensitive to indicators and regions. We obtained a similar classification with nighttime heat waves (not shown).