Abstract
The Lake Chad Basin is Africa’s largest endorheic basin. Because water supply for the rural population and most of the urban population depends on groundwater, assessment of groundwater recharge is crucial. Recharge sources for the upper Quaternary aquifer are precipitation, rivers, and swamps. Using water chemistry, and environmental (18O, 2H, 3H) and carbon (14C) isotopes, recharge processes can be assessed and groundwater ages roughly estimated. For this purpose, more than 1,000 samples from groundwater, surface water and precipitation were analysed for hydrochemistry and environmental stable isotopes. Furthermore, 3H measurements and 14C values of dissolved inorganic carbon for groundwater from the northeastern part of the Basin are included in the evaluation. The environmental isotope distribution shows recent recharge from precipitation north of Lake Chad (Kanem Region), where very low 3H values indicate occurrence before the 1960s bomb peak. Focused recharge from fresh river water is typical for Salamat Region in south Chad and the Komadugu Yobe wetlands between Nigeria and Niger. Slightly high δ-values in water occur in the Waza Logone area between Chad and Cameroon. Groundwater along the Lake Chad shore and the Bahr el Ghazal corridor show high δ-values (δ18O –0.78 to 7.45‰, δ2H –13.6 to 30.8‰). Recharge is caused by surface water that undergoes evaporative processes before percolation. Groundwater ages of 600–4,150 years, estimated from 14C analyses combined with high SO4 concentrations, along the Bahr el Ghazal indicate that recharge was caused by residuals of the Mega Lake before it dried out completely.
Zusammenfassung
Das Tschadseebecken ist Afrikas größtes endorheisches Einzugsgebiet. Da die Wasserversorgung der Landbevölkerung und des größten Teils der Stadtbevölkerung vom Grundwasser abhängt, ist die Einschätzung der Grundwasserneubildung von entscheidender Bedeutung. Neubildungsquellen für den oberen Quartären Grundwasserleiter sind Niederschläge, Flüsse und Feuchtgebiete. Anhand von Wasserchemie, Umwelt- (18O, 2H, 3H) und Kohlenstoff- (14C) Isotopen können Neubildungsprozesse bewertet und das Grundwasseralter grob abgeschätzt werden. Dazu wurden mehr als 1.000 Proben aus Grundwasser, Oberflächenwasser und Niederschlag auf Hydrochemie und umweltstabile Isotope analysiert. Weiterhin fließen 3H-Messungen und 14C-Werte von gelöstem anorganischem Kohlenstoff für Grundwasser aus dem nordöstlichen Teil des Beckens in die Auswertung ein. Die Verteilung der Umweltisotope zeigt rezente Neubildung durch Niederschläge nördlich des Tschadsees (Kanem Region), wo sehr niedrige 3H-Werte auf eine Neubildung vor dem Bombenpick der 1960er Jahre hinweisen. Eine fokussierte Neubildung aus frischem Flusswasser ist typisch für die Salamat Region im Süden des Tschads und das Komadugu Yobe Feuchtgebiet zwischen Nigeria und Niger. Leicht erhöhte δ-Werte im Wasser treten im Waza-Logone Feuchtgebiet zwischen Tschad und Kamerun auf. Das Grundwasser entlang des Tschadseeufers und des Bahr el Ghazal Korridors weist hohe δ-Werte auf (δ18O –0.78 bis 7.45‰, δ2H –13.6 bis 30.8‰). Die Neubildung wird durch Oberflächenwasser verursacht, das vor der Versickerung Verdunstungsprozessen unterzogen wird. Grundwasseralter von 600 bis 4150 Jahren, abgeschätzt aus 14C-Analysen in Kombination mit hohen SO4-Konzentrationen, entlang des Bahr el Ghazal deuten darauf hin, dass die Neubildung durch Überreste vom Mega Lake verursacht wurde, bevor er vollständig austrocknete.
Résumé
Le Bassin du lac Tchad est le plus grand bassin endoréique d’Afrique. L’approvisionnement en eau de la population rurale et de la majeure partie de la population urbaine dépendant des eaux souterraines, l’évaluation de la recharge des aquifères est cruciale. Les sources de recharge de l’aquifère du Quaternaire supérieur sont les précipitations, les rivières et les zones humides. L’utilisation de la chimie de l’eau et des isotopes environnementaux (18O, 2H, 3H) et du carbone (14C) permet d’évaluer les processus de recharge et d’estimer approximativement l’âge des eaux souterraines. À cette fin, plus de 1,000 échantillons d’eaux souterraines, d’eaux de surface et de précipitations ont été analysés pour l’hydrochimie et les isotopes stables environnementaux. De plus, des mesures de 3H et des valeurs de 14C du carbone inorganique dissous pour les eaux souterraines de la partie nord-est du bassin sont incluses dans l’évaluation. La distribution des isotopes environnementaux montre une recharge récente par précipitation au nord du lac Tchad (Région du Kanem), où de très faibles valeurs de 3H indiquent une survenue avant le pic dû aux essais nucléaires des années 1960. Une recharge concentrée à partir de l’eau douce de la rivière est typique pour la Région de Salamat au sud du Tchad et les zones humides de Komadugu Yobe entre le Nigéria et le Niger. Des valeurs de δ légèrement élevées dans l’eau sont rencontrées dans la région de Waza Logone entre le Tchad et le Cameroun. Les eaux souterraines le long de la rive du lac Tchad et du corridor du Bahr el Ghazal présentent des valeurs de δ élevées (δ18O –0.78 à 7.45‰, δ2H –13.6 à 30.8‰). La recharge est causée par l’eau de surface qui subit des processus d’évaporation avant infiltration. Les âges des eaux souterraines de 600 à 4150 ans le long du Bahr el Ghazal, estimés à partir d’analyses de 14C et combinés à des concentrations élevées de SO4, indiquent que la recharge a été causée par les résidus du Mega Lake avant qu’il ne s’assèche complètement.
Resumen
La cuenca del lago Chad es la cuenca endorreica más grande de África. Dado a que el suministro de agua para la población rural y la mayoría de la población urbana depende de las aguas subterráneas, la evaluación de la recarga de los acuíferos es crucial. Las fuentes de recarga para el acuífero del Cuaternario superior son las precipitaciones, los ríos y los humedales. El uso de la química del agua y los isótopos ambientales (18O, 2H, 3H) y carbono (14C) permite evaluar los procesos de recarga y estimar aproximadamente la edad del agua subterránea. Con este fin se analizaron más de 1,000 muestras de aguas subterráneas, superficiales y de precipitación para hidroquímica e isótopos ambientales estables. En la evaluación también se incluyen mediciones de 3H y valores de 14C de carbono inorgánico disuelto en las aguas subterráneas de la parte noreste de la cuenca. La distribución de isótopos ambientales muestra una recarga reciente por precipitación al norte del lago Chad (región de Kanem), donde valores muy bajos de 3H indican ocurrencia antes del pico de las pruebas nucleares en la década de 1960. La recarga concentrada de agua dulce de río es típica de la región de Salamat en el sur de Chad y de los humedales de Komadugu Yobe entre Nigeria y Níger. En el área de Waza Logone, entre Chad y Camerún, los valores de δ en el agua son ligeramente elevados. Las aguas subterráneas a orillas del lago Chad y a lo largo de Bahr el Ghazal muestran valores altos de δ (δ18O –0.78 a 7.45‰, δ2H –13.6 a 30.8‰). La recarga es causada por el agua superficial que sufre procesos de evaporación antes de infiltrar. Edades del agua subterránea de 600 a 4150 años, estimadas a partir de análisis de 14C combinados con altas concentraciones de SO4, a lo largo de Bahr el Ghazal indican que la recarga fue causada por restos del Mega Lake antes de que éste se secara por completo.
摘要
乍得湖盆地是非洲最大的内流盆地。由于农村人口和大部分城市人口的供水都依赖于地下水,因此对地下水补给的评估非常关键。上第四纪含水层的补给来源包括降水、河流和沼泽。通过利用水化学、环境(18O,2H,3H)和碳(14C)同位素,可以评估补给过程,并大致估计地下水的年龄。为此,对地下水、地表水和降水的1,000多个样品进行了水化学和环境稳定同位素的分析。此外,对来自盆地东北部的地下水的3H测量和溶解无机碳的14C值也包括在评估中。环境同位素的分布显示,在乍得湖北部(Kanem区),降水导致的最近补给是通过非常低的3H值,表明在20世纪60年代之前发生的。来自淡水河水的有针对性的补给是乍得南部的Salamat区和尼日利亚和尼日尔之间的Komadugu Yobe湿地的典型情况。在乍得和喀麦隆之间的Waza Logone地区,水中的δ值略高。乍得湖岸和Bahr el Ghazal走廊的地下水显示出高δ值(δ18O –0.78 到 7.45‰, δ2H –13.6 到 30.8‰)。补给是由于地表水在入渗之前经历了蒸发。由14C分析结合高SO4浓度估算得出的Bahr el Ghazal沿岸的地下水年龄为600至4150年,表明补给是由于Mega Lake彻底干涸前的残留物引起的。
Resumo
A Bacia do Lago Chade é a maior bacia endorreica da África. Como o abastecimento de água para a população rural e a maior parte da população urbana depende das águas subterrâneas, a avaliação da recarga das águas subterrâneas é crucial. As fontes de recarga para o aquífero quaternário superior são a precipitação, rios e pântanos. Usando a química da água e os isótopos ambientais (18O, 2H, 3H) e de carbono (14C), os processos de recarga podem ser avaliados e as idades das águas subterrâneas aproximadamente estimadas. Para isso, mais de 1,000 amostras de águas subterrâneas, águas superficiais e precipitação foram analisadas para hidroquímica e isótopos estáveis ambientais. Além disso, medições de 3H e valores de 14C de carbono inorgânico dissolvido para águas subterrâneas da parte nordeste da Bacia estão incluídas na avaliação. A distribuição de isótopos ambientais mostra recarga recente da precipitação ao norte do Lago Chade (região de Kanem), onde valores muito baixos de 3H indicam ocorrência antes do pico da bomba da década de 1960. A recarga concentrada da água doce do rio é típica da região de Salamat, no sul do Chade, e das zonas úmidas de Komadugu Yobe, entre a Nigéria e o Níger. Valores ligeiramente altos de δ-valores na água ocorrem na área de Waza Logone, entre Chade e Camarões. As águas subterrâneas ao longo da margem do Lago Chade e do corredor de Bahr el Ghazal apresentam altos valores de δ-valores (δ18O –0.78 a 7.45‰, δ2H –13.6 a 30.8‰). A recarga é causada pelas águas superficiais que passam por processos evaporativos antes da percolação. As idades das águas subterrâneas de 600 a 4,150 anos, estimadas a partir de análises de 14C combinadas com altas concentrações de SO4, ao longo do Bahr el Ghazal indicam que a recarga foi causada por resíduos do Mega Lago antes de secar completamente.
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Introduction
Water availability worldwide is under threat because of rapid population growth and the consequent increase in withdrawal for domestic, industrial, and irrigation uses (Mohan et al. 2018). As a result, both surface water and groundwater resources are experiencing overexploitation. Regarding groundwater, 37 of the world’s largest aquifer systems were studied by Richey et al. (2015a, b), of which 21 were reported to be depleted. When adding the climate change factor, it becomes clear that there is an urgent need for adequate management of these resources to ensure social and economic development.
Groundwater recharge is often the limiting factor for groundwater withdrawal under sustainable conditions (Döll and Flörke 2005); thus, the estimation of present recharge is critical, especially in arid and semiarid areas. This is particularly true for the 400-km-wide band across Africa known as the Sahel region, where large aquifers are present, but data collection concerning climate, precipitation, and groundwater head is very scarce due to lack of monitoring stations.
The Lake Chad Basin (LCB) is an endorheic basin located in the central part of northern Africa. It has an area of 2.4 million km2 and is inhabited by approximately 45 million people (LCBC 2016). Because of its location and extension, the LCB mirrors the climatological, hydrological, and societal situation of the semiarid Sahel region. It lies in an area of transition from perennial to ephemeral river systems and where reliable water supply using surface water suffers uncertainty. Therefore, it is often subject to conflicts among water uses (Ashton 2002), especially in the surroundings of the Lake Chad (Rizzo 2015). It is here where effective water management is needed the most.
Studies on groundwater recharge in arid to semiarid areas involve mainly local or semiregional evaluation. They often use the chloride mass balance technique (Gaye and Edmunds 1996; Edmunds et al. 2002; Edmunds and Tyler 2002) combined with stable water isotopes (Allison and Hughes 1983; Barnes and Allison 1988; Barnes et al. 1989; Leduc et al. 2000; Beyer et al., 2015; Adomako et al. 2010; Gaj et al. 2016; Tewolde et al. 2019; Goni et al. 2019; Mahamat Nour et al. 2022) and hydrochemistry (Njitchoua et al. 1995; Edmunds et al. 1999; Zagana et al. 2007a). Recharge has also been assessed by means of the mass balance equation (Zagana et al. 2007b; Ndubuisi 2007) and combination of empirical models (Adelana et al. 2006). Additionally, modelling of 3H and 14C (Favreau et al. 2002) and modelling of environmental isotopes by including evaporative fractionation in soil profiles (Zhou et al. 2021) or the analysis of aquifer hydrodynamic characteristics (Ngounou Ngatcha et al. 2007) have been used to determine recharge. Recharge distribution has also been mapped using satellite-based thermal data (Leblanc et al. 2003). Many of these studies were included in a global assessment of groundwater recharge in semiarid areas by Scanlon et al. (2006).
Using numerical flow modelling, diffuse recharge has been calibrated for the whole LCB (Boronina et al. 2005; Vaquero et al. 2021) and limited regions like the Waza Logone area (Candela et al. 2014; Nkiaka et al. 2018), the Chari Baguirmi region (Massuel 2001), and the Komadugu Yobe River region (Leblanc 1997; Zairi 2008; Genthon et al. 2015). Diffuse recharge distribution has been also determined based on chloride-36 analyses throughout the area (Bouchez et al. 2019).
This work will concentrate on the distribution of environmental isotopes combined with 3H values and chemical composition of groundwater as well as assessment of groundwater age through 14C, to attempt to define areas of present and past recharge throughout the whole LCB. A very valuable and extensive amount of data is available at the Lake Chad Basin Commission (LCBC) from a series of cooperation projects with the German government.
Study area
Location, climate, and hydrology
The LCB is located in the central part of northern Africa and extends from 5 to 25°N and from 7 to 25°E (Fig. 1).
Due to its size, the LCB expands over various climates and ecosystems. Following the updated Köppen-Geiger climate classification (Peel et al. 2007), the northern part of the basin corresponds to Saharan climate (hot arid desert) with very low precipitation, mean annual temperature above 18 °C, daily temperature amplitude greater than 35 °C, and annual temperature amplitude greater than 60 °C (White 1983). Southward lies the 400-km-wide Sahelian band (hot arid steppe). It is characterised by mean annual temperatures between 26 and 30 °C and precipitation between 150 and 500 mm (White 1983). Precipitation occurs over 3–4 months and is closely linked to the West African Monsoon, which is known for its extremely variable manifestation (Hall and Peyrillé 2006). To the south, the tropical region (tropical savannah) is encountered. Here mean annual temperature varies in a range of 24–28 °C and mean annual precipitation is from 500 to 1,400 mm (White 1983) or 1,700 mm according to ERA5 data for the period 1979–2005.
From a hydrological point of view, the most prominent feature in the region is Lake Chad, which receives most of its water from the tropical savannah through the Chari-Logone River system (Fig. 1). The Komadugu Yobe River usually provides small flow to the lake (Olivry et al. 1996), but it has become insignificant in recent decades because of flow retentions and diversions (Geerken et al. 2011). Several wetlands and periodically inundated areas spread over the LCB, like the lakes Chad and Fitri, the Waza Logone wetlands on the border between Chad and Cameroon, the Komadugu Yobe wetlands in Nigeria, the Salamat wetland between Chad and Central African Republic, and the Massénya wetland in Chad (Fig. 1).
Hydrogeology
The upper unconfined to semiconfined aquifer is composed of Quaternary aeolian sands (Fig. 1) interbedded by fluvio-lacustrine silt and clay in areas prone to periodical flooding along the Lake Chad shore and the wetlands (Durant and Mathieu 1980; Schneider and Wolff 1992; Moussa et al. 2013). This large transboundary aquifer extends over most of the LCB and has an area of ~500,000 km2 (Leblanc et al. 2007) with an average thickness of 100 m that varies from 190 m in the Kanem dunes to the north in Chad to a few meters towards the boundaries in the south (UNESCO 1969; Bouchez et al. 2019). It is known as the Upper Aquifer of the Chad Formation in Nigeria (Barber 1965; Eberschweiler 1993a, b) and is an important groundwater resource for Cameroon, Chad, and Niger, whereas in Nigeria it is used mainly for local rural water supply (Miller et al. 1968), due to low thickness and discontinuity (Barber 1965).
The Quaternary aquifer is underlain by the upper Pliocene (Fig. 2), an aquitard composed of up to 300 m of greenish clay, and the lower Pliocene, represented by fine to coarse sand deposits, which often cannot be differentiated from the underlying Continental Terminal (CT) (Schneider and Wolff 1992). The lower Pliocene (Fig. 2), known as the Middle Aquifer of the Chad Formation in Nigeria (Barber 1965), is encountered at depths between 250 and 300 m and is artesian in the surroundings of the Lake Chad. It provides groundwater to Nigerian cities in the basin, like Maiduguri.
The Oligo-Miocene CT (Fig. 2), composed of fluvio-lacustrine deposits, is characterised by an alternation of sandstone and clay banks (Lang et al. 1990; Eberschweiler 1993a) of variable thicknesses that can reach up to 600 m, but on average is 100 m (Eberschweiler 1993b). This is the lowest aquifer that lies directly over the granitic basement complex (Arad and Kafri 1975) or in discordance on Cretaceous formations (Massuel 2001). It is known as the Lower Aquifer of the Chad Formation in Nigeria (Barber 1965) and its groundwater quality is very poor due to mineralisation (Eberschweiler 1993b). Where the Cretaceous formations are present (Cameroon and Niger), they lay on the crystalline basin; however, it is not certain that they extend throughout the whole basin (Massuel 2001).
Recharge
Presently, the Quaternary aquifer in the LCB receives recharge through seepage from wetlands (Tewolde et al. 2019) and perennial rivers (Bouchez et al. 2019), as well as along the Lake Chad shore (Isiorho et al. 1996); however, because of river scarcity in the LCB, the largest volume of recharge results from diffuse rainfall. Estimations vary considerably depending on the study area and the method used (Table 1). Values between 2 mm/annum have been assessed in southern Niger (Leduc et al. 2000) and 16–30 mm/annum in northern Nigeria (Edmunds et al. 2002). For Chad, values fluctuating from less than 1 mm/annum in the north, 3–19 mm/annum in the Salamat region, and in the range of 117–163 mm/annum in the Waza Logone region have been reported (Tewolde et al. 2019). Bouchez et al. (2019) estimate a diffuse precipitation recharge of 16±27 mm/annum throughout the basin and conclude that this recharge volume is much higher than the actual withdrawals in the LCB, confirming findings from Bonsor et al. (2018). Using GRACE products and land surface models, they found that, although seasonal variations can be identified, no long-term trend in groundwater levels is visible.
Groundwater quality
Groundwater quality of the Quaternary aquifer is variable and depends on residence time in the hosting rocks (Bouchez et al. 2019). According to Arad and Kafri (1975), calcium-bicarbonate isotopically light groundwater is encountered in the south and southwest of the LCB and is an indication of present recharge by precipitation. General groundwater flow is towards the northeast and composition changes to distinctive chemical groups along flow paths (Arad and Kafri 1975). Brines and evaporates can be found in many depressions between the Kanem sand dunes north of the lake (Eugster and Maglione 1979), along the Bahr el Ghazal to the northeast of the lake (Schneider and Wolff 1992) as well as in its northern pool of the lake, which has been more or less dry since 1983 (Neukum et al. 2017).
Groundwater quality of the Quaternary Upper Aquifer in Nigeria is in general excellent for drinking water purposes, apt for industrial use, and suitable for irrigation except on clay soils (Barber 1965). Good drinking water quality has also been reported for the Cameroon part of the basin (Bello et al. 2019).
It is known that excess sodium is common in the Chari Baguirmi region (Abderamane et al. 2012) and the northern pool of the Lake Chad (Neukum et al. 2017). Because the Quaternary aquifer is composed of weathered igneous rocks from the granitic basement, Arad and Kafri (1975) conclude that these igneous rocks are the source of sodium in groundwater through alteration of plagioclase, particularly albite in kaolinite (Abderamane et al. 2012). Potassium is also present in these rocks at similar concentrations, but it tends to precipitate and thus is not representative in groundwater chemistry.
Fluoride is present in the area (Fantong et al. 2010; Bura et al. 2018), which is of geogenic origin and not widespread. Nitrate pollution as a result of leaking pit-latrines and a general lack of hygiene has been reported from numerous cities within the basin (Ngounou Ngatcha and Daïra 2010; Goni et al. 2019; Bon et al. 2020). It is also a problem in agricultural regions, due to overuse of fertilizers and in pastoral areas because of mismanagement of water points (Vassolo and Daïra 2012; Huneau 2017).
Materials and methods
Groundwater chemistry combined with environmental isotopes (δ18O and δ2H), 3H, and 14C are used to determine the groundwater recharge of the Quaternary aquifer in the LCB. Furthermore, mapping the distribution of groundwater quality and isotopes allows for depicting areas that presently receive recharge as well as areas that do not participate in the actual water cycle.
Laboratory results from regular groundwater sampling throughout the basin over the last 12 years are available. In total, 1,267 full chemical analyses, 1,203 environmental isotopes analyses, 142 tritium analyses, and seven carbon-14 analyses exist at the LCBC from a series of cooperation projects with the German Federal Institute for Geosciences and Natural Resources (BGR). Additionally, environmental isotopes in 386 event-based precipitation samples, collected at six stations scattered in the basin, as well as 110 samples for the Chari River in N’Djamena over the period July 2016–September 2021, are available. Because all analyses were performed in the same laboratories, relative comparability of the results is very high. Ion balance was less than 10% for 1,128 (97.4%) samples and less than 5% for 1,128 (89%) samples.
Coordinates of the sample points were recorded during sampling campaigns by means of a Garmin™ GPS device. Temperature, electrical conductivity (EC), and pH were measured on-site using a digital multi-parameter instrument (WTW™-Multi 3430 and HACH HQ40d with IntelliCAL™ electrodes). Groundwater was extracted either by pumping with the installed pump, a submersible pump (Grundfoss™MP1), or a bailer. Sampling from chemical analyses consisted in filling a 100-ml PVC bottle with filtered and HNO3-acidified water for cation analysis. Addition of HNO3 lowers the pH value to ~2, avoiding precipitation, bacterial growth, adsorption on the bottle’s wall, etc. Furthermore, a 500-ml PVC bottle was filled with unfiltered and nonacidified water for anion analysis. Samples were collected after rinsing the bottles three times with water from the sampling site and kept in a cool box during the field campaign. For isotope analyses, 30-ml amber glass bottles with PE-seal caps filled with untreated and unfiltered water were used. In the case of tritium and 14C, 1,000-ml PE bottles were filled with unfiltered and untreated water. Samples were stored at 6 °C until the time of packaging, and were then airfreighted to the laboratory in Hanover (Germany) in cool boxes packed with cooling elements.
Concentrations of major and minor ions were measured using a DIONEX ICS-3000 ion chromatograph (Cl, Br, F, NO3, NO2, SO4), a SPECTRO ARCOS ICP-OES instrument (Na, K, Ca, Mg, P, Fe, Mn, Al, Si), and a UNICAM UV 300 photometer (NH4, NO2, PO4). Commercial standard solutions are used for daily calibration and limits of quantitation are determined by 10-point calibration according to the DIN 32645 standard. HCO3 and CO3 concentrations were determined with a SCHOTT Titroline Alpha Plus automatic titration system according to a modified DIN 38409-H7-2 standard by evaluation of titration curve shapes for the identification and quantitation of these species. The contribution of PO4 to alkalinity was estimated from ICP-OES concentration data.
All stable isotopes (18O and 2H) values were determined using a PICARRO L2130-i and L2140-i cavity ring-down laser spectrometers. Samples were measured at least four times and the reported value is the mean one. All values are given in delta notation in per mill (‰) vs. Vienna Standard Mean Ocean Water (VSMOW). Raw data were checked for organic contamination using the software ChemCorrect (unaltered software settings), then corrected for memory effects and drift. Furthermore, they were normalized to the VSMOW/SLAP scale. External reproducibility, defined as standard deviation of a quality check standard during all runs, was better than 0.20 and 0.8‰ for δ18O and δ2H, respectively.
Tritium was measured at the Bremen University, Germany, by mass spectrometry of its decay product Helium-3. After degassing, each sample was stored for ~6 months in glass bulbs. Next, the glass bulbs were connected to the sample inlet system and unsealed under high-vacuum conditions. Accumulated Helium-3 was separated from water and analysed for Helium-3 and Helium-4 with a sector field mass-spectrometer (MAP 215-50). Helium-4 serves to quantify sample contamination by air. The system is calibrated by defined amounts of atmospheric air and is able to detect 0.01 TU or 0.6 mBq/L in water.
Carbon-14 was measured by Beta Analytics Inc. (USA) by counting the number of 14C atoms present in the sample through accelerator mass spectrometry (AMS).
Deuterium-excess—d-excess (‰) = δ2H (‰) – 8 × δ18O (‰)—is used to determine evaporation effects in the recharge processes. It depends on evaporation conditions at the ocean and varies with cloud transport to the precipitation site (Bershaw 2018). According to the Global Network of Isotopes in Precipitation (GNIP), its global average value under oceanic evaporation conditions is 10‰ (Florea et al. 2017), when air humidity is above 85% (Fritz and Fontes 1980; Clark and Fritz 1997). Under evaporative conditions, the residual water is enriched in both δ18O and δ2H, but, because the relative enrichment of δ18Ο is larger than for δ2H, d-excess results are lower than 10‰.
Results and discussion
Groundwater recharge areas can be delineated using environmental isotopes and groundwater quality data. Furthermore, it is possible to describe recharge processes using the isotopic characteristics of groundwater.
Isotopic composition
There are two groundwater recharge sources in the LCB: precipitation and surface water (rivers, lakes, and wetlands). These sources have dissimilar isotopic compositions and, thus, mark groundwater differently.
Concerning precipitation, the project has installed six rain collectors in the basin at N’Djamena, Mao, Bol, and Abéché in Chad as well as at Maiduguri and Kano in Nigeria (Table 2; Fig. 3). Isotope values for the Kano station are only available for the rainy season in 2018. In the case of Maiduguri, the study attained samples for four rainy seasons (2018–2021), but analyses are available only for 2018. These two stations were not considered for further analyses. Analyses for Bol and Abéché do not include samples from 2021.
According to Table 2, groundwater presently recharged by precipitation should be close to the weighted average isotope values of precipitation with δ18O values between –3.9‰ and –5.9‰ and δ2H values in the range of –21.5 to –36.6‰. Precipitation at Bol presents the most depleted concentrations for both isotopes, probably due to its proximity to the Lake Chad. The open surface water is able to supply depleted isotope values and, thus, change the composition of precipitation locally.
Since 2016, the most depleted values of δ18O and δ2H in the Chari River at N’Djamena are –4.6 and –27.5‰, respectively, which correspond to the mean weighted average of precipitation in N’Djamena (–5‰, –27‰). This means that during high water, the flow originates from rainfall. The most δ2H-enriched values are 3.9‰ for δ18O and 19.8‰ for δ2H. The water line for the Chari River (Fig. 4a) results in δ2H = 5.0 × δ18O–1.1. Mean values for δ18O and δ2H are –0.62 and –4.2‰, respectively. In N’Djamena, the Chari water line intercepts the local meteoric water line at δ18O = –4.0‰ and δ2H = –21.1‰.
A regression line for groundwater is defined by δ2H = 5.5 δ18O – 4.9 (Fig. 4a). Mean values for δ18O and δ2H are –2.2 and –17.2‰, respectively. δ2H varies between –7.0 and 12.9‰, and δ2H between –49.1 and 66.8‰. In the graph of Deuterium excess (d-excess) vs. δ18O (Fig. 4b), the regression lines for river water and groundwater are steeper compared to the local precipitation line. This is an indication of evaporation effects experienced by both river water and groundwater.
Mahamat Nour (2019) reported that the Quaternary aquifer discharges into the Chari and Logone rivers during the dry season and exfiltrating groundwater had a mean isotopic composition of –1.5 and –7.2‰ for δ18O and δ2H, respectively for the years 2013, 2015, and 2016. Here, the δ-values are more positive compared to the mean weighted precipitation values (Table 2), indicating evaporation effects during recharge.
Mapping the distribution of δ2H (‰) in the LCB allows for depicting the areas in which recharge takes place. Diffuse recharge from recent precipitation (white dots) occurs in the Kanem region (Fig. 5). The orange dots in this region indicate more positive δ-values and thus, evaporation in the recharge process. Although precipitation in the area is very low, it appears that recharge can ensue because of the concentration of rainwater along the interdunal valleys. Present recharge also occurs in the Chari Baguirmi region in central Chad, where precipitation amounts are large enough to allow infiltration and percolation. Groundwater in the surroundings of the wetlands Salamat in south Chad and Komadugu Yobe at the border between Nigeria and Niger also show present recharge. In this case, it is either focused recharge during high water levels, when rivers are mainly fed by rainfall, or diffuse recharge through ponding water in the wetlands. The map (Fig. 5) indicates present groundwater recharge in the Waza Logone area with more positive δ-values (orange dots), which is the result of recharge with surface water that has experienced some evaporation. Very positive δ-values are encountered in the northern part and along the eastern shore of Lake Chad as well as along the lake’s shore and the Bahr el Ghazal (dark green dots). In these areas, recharge is caused by surface water that heavily evaporates before percolating.
Deuterium-excess values for precipitation in N’Djamena vary from –7‰ (2017) to 19‰ (2018) with a value of 10‰ for both median and average (Table 3), which indicates an oceanic origin of precipitation that does not experience evaporation when transported across the continent. This confirms findings by Goni et al. (2021). They report that recharge in the LCB takes place in the middle of the rainy season, when precipitation events are strong and air humidity above 85% and thus, with d-excess values of approx. 10‰. Deuterium-excess values for the Chari River, the other possible source of recharge, are in the range of –12 to 12‰ with a median of 2‰ and an average of 1‰, which clearly indicates evaporation effects (Table 3). In groundwater, d-excess varies from –37 to 12‰ with a median of 1‰ and an average of 3‰. Because the lowest d-excess values in groundwater are much lower than in precipitation or Chari River, it can be concluded that ponds or wetlands, where large evaporation is possible, also produce recharge.
The d-excess distribution for the LCB (Fig. 6) shows direct recharge without evaporation at the southern rim of the Quaternary aquifer (blue dots) meaning that direct recharge from precipitation without or only little evaporation effects takes place here. Values of d-excess close to 10‰ appear also along the rivers; thus, they only recharge the Quaternary aquifer during high water levels, when river water is composed mainly of precipitation water. Groundwater in the northern pool of Lake Chad, as well as along the lake’s shore and the Bahr el Ghazal, show very negative d-excess values (red dots), which confirms the fact that here recharge is produced by heavily evaporated water.
Tritium measurements from 142 samples in Kanem and the Chari Baguirmi region as well as seven 14C analyses were available to evaluate the time of recharge (Fig. 7). Most of the samples show very low tritium values (<1.5 TU, light blue dots) demonstrating that recharge occurred mainly before the bomb peak in the 1960s. However, samples along the Lake Chad shore show recharge from 55 years ago (3H > 2.5 TU, green squares) produced by lateral inflow from the lake at its “normal” state and confirm finding from Mahamat Nour et al. (2022). Lake Chad in the 1960s has been defined as “normal” (Lemoalle et al. 2012) and is characterised by water levels between 281 and 282 m above mean sea level (amsl), an extension of ~20,000 km2, numerous dune islands, and occasional marshy vegetation on the shores (Lemoalle et al. 2012). According to tritium results, the present recharge by precipitation (values between 1.5 and 2.5 TU, dark blue dots) takes place in some locations scattered throughout the LCB (Fig. 6). Carbon-14 values along the Bahr el Ghazal estimate groundwater ages between 600 and 4,150 years (Fig. 7). These values confirm findings from Bouchez et al. (2019), who reported premodern recharge for this area.
In summary, water isotopes allow for defining recharge mechanisms within the LCB. Results are presented in Table 4.
Chemical composition
The chemical composition of groundwater also reflects the recharge areas in a semiarid climate. Newly recharged groundwater is characterised by low values of EC, because precipitation shows generally low values of EC. In N’Djamena, 12 values of EC in precipitation have been recorded for May to July 2020. Values vary from 16 to 48 μS/cm with an average of 27 μS/cm.
Electrical conductivity was measured in 1,263 groundwater samples in the LCB. Values vary largely from 31 to 8,993 μS/cm with an average of 689 μS/cm (Fig. 8). Altogether, 1,046 (83%) of the values show an EC value below 1,000 μS/cm and thus reflect the general low groundwater mineralization of the Quaternary aquifer. High values of EC (>2,000 μS/cm) occur in the northern part and southern rim of Lake Chad, along the Bahr el Ghazal, and in the northern part of the Chari Baguirmi.
Sulphate concentration in 1,267 groundwater samples throughout the LCB vary from below the detection limit to 4,403 mg/L with an average of 98.5 mg/L. A large number of samples (1,197 samples, 94.4 %) have values below the WHO (2022) guideline of 500 mg/L. Samples with sulphate concentrations above the WHO limit also show high EC values.
It is possible to distinguish two different trends of EC–SO4. The increasing trend of low slope corresponds to the northern part of Lake Chad, where large values of EC do not correlate with sulphate concentration (Fig. 9a) but are the result of high chloride concentrations (Fig. 9b) due to evaporation. In this area, recharge is caused by lake water that experiences large evaporation before percolation. The steeper trend (Fig. 9a) belongs to the boreholes along the Bahr el Ghazal, where EC correlates with high sulphate concentrations that occur in the area. Eugster and Maglione (1979) postulated that sulphate could originate from oxidation of sulphides or organic matter trapped in clays deposited by the Mega Lake Chad (10,000–2,000 years BP). Seven groundwater samples along the Bahr el Ghazal area were dated by means of 14C. Calculated ages vary between 600 and 4,150 years with an average age of 2,176 years confirming that groundwater in the Bahr el Ghazal was recharged at the time of the Mega Lake Chad occurrence. This area does not receive recharge presently and is less affected by evaporation, which is depicted by a lower correlation between EC and Cl (Fig. 9b).
Conclusions
The combination of isotope and chemical analyses of groundwater allows one to delineate areas of recharge in the LCB and to determine the age of the groundwater. Actual diffuse recharge occurs in the Kanem dunes. Although precipitation in the area is very low, recharge does occur because of the concentration of rainwater along the interdunal valleys. The Chari Baguirmi area in central Chad, the wetlands of Salamat in south Chad, and Komadugu Yobe at the border between Nigeria and Niger also experience recent diffuse recharge from precipitation. However, in these areas focused recharge during floods prevails, when the rivers transport mainly rainfall. Tewolde et al. (2019) estimated diffuse mean annual groundwater recharge in the range of 3–19 mm and focussed recharge of 111 mm for Salamat wetlands.
The Waza Logone area is characterised by slightly enriched groundwater, which is the result of recharge with surface water that has experienced some evaporation. Here recharge has been estimated between 117 and 163 mm/annum (Tewolde et al. 2019). Heavily 2H- and 18O-enriched groundwater is found in the northern part of Lake Chad as well as along the lake’s shore, where recharge is caused by lake water that severely evaporates before percolating. However, present recharge seems to be very low. Tewolde et al. (2019) estimated annual recharge between 0.6 and 0.8 mm/annum.
Groundwater along the Bahr el Ghazal is 2H and 18O-depleted with large negative values of d-excess, which points to a recharge with evaporated surface water. Groundwater also presents large contents of sulphate probably due to oxidation of sulphides or from organic matter trapped in clays deposited by the Mega Lake Chad (10,000–2,000 years BP). Measurement of 14C translates into groundwater ages varying between 600 and 4,150 years, which is defined as premodern by Bouchez et al. (2019).
In general, groundwater of the Quaternary aquifer has low electrical conductivity (EC), which is an indication of recently recharged water. Values above 2,000 μS/cm are only present in the northern part and the southern rim of Lake Chad, the northern part of Chari Baguirmi, and along Bahr el Ghazal. The high EC values in the northern part and southern rim of Lake Chad are evaporation-induced and correlate with chloride. However, the elevated values along the Bahr el Ghazal correlate with SO4, which could originate from oxidation of sulphides or organic matter trapped in clays deposited by the Mega Lake Chad.
Recommendations to water resource managers
Although recharge occurs in most of the LCB, protection of the wetlands is urgently needed. The largest amount of recharge takes place in these wetland areas and they should be managed to maintain quantity and quality. It is highly recommended to avoid installation of dams or other engineering structures that could lead to their desiccation. If this occurs, not only recharge would reduce substantially in the basin, but also biodiversity would reduce significantly. Furthermore, actions should be taken to avoid pollution, e.g. misuse of fertilisers or lack of effluent treatment facilities in towns and villages.
Use of groundwater along the Bahr el Ghazal could be of concern because of the high content of salts, especially sulphate. It is recommended not to install any wells for water supply before ensuring the good quality of groundwater.
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Acknowledgements
The authors express their gratitude to Anna Degtjarev and her team for their numerous chemical analyses in laboratory. We thank the reviewers for helping us to improve the quality of this manuscript.
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Open Access funding enabled and organized by Projekt DEAL. We appreciate the financial support from the German Federal Ministry of Economic Cooperation and Development (BMZ), Project No. BMZ PN 2018.2225.3.
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Vassolo, S., Gröschke, M., Koeniger, P. et al. Groundwater recharge processes in the Lake Chad Basin based on isotopic and chemical data. Hydrogeol J 32, 149–165 (2024). https://doi.org/10.1007/s10040-023-02699-2
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DOI: https://doi.org/10.1007/s10040-023-02699-2