Groundwater potential mapping in semi-arid region of Northern Nigeria by integrating analytic hierarchy process and GIS

Saidu, Abdulmutallib A.; Aldrees, Ali; Dan'azumi, Salisu; Abba, Sani I.; Hamza, Salahu M.

doi:10.3389/frwa.2024.1484753

ORIGINAL RESEARCH article

Front. Water, 15 November 2024

Sec. Water and Critical Zone

Volume 6 - 2024 | https://doi.org/10.3389/frwa.2024.1484753

This article is part of the Research Topic Groundwater Vulnerability: Modern Experimental, Modeling, and Mapping Methods View all 3 articles

Groundwater potential mapping in semi-arid region of Northern Nigeria by integrating analytic hierarchy process and GIS

$\r\nAbdulmutallib A. Saidu$ Abdulmutallib A. Saidu¹

Ali Aldrees²

Salisu Dan'azumi²^*

Sani I. Abba³

Salahu M. Hamza⁴

¹Department of Civil Engineering, Bayero University Kano, Kano, Nigeria
²Department of Civil Engineering, College of Engineering in Alkharj, Prince Sattam bin Abdulaziz University, Al-Kharj, Saudi Arabia
³Department of Civil Engineering, Prince Mohammad bin Fahd University, Al Khobar, Saudi Arabia
⁴Department of Civil Engineering, Hussaini Adamu Polytechnic, Kazaure, Jigawa, Nigeria

Groundwater resource management in drylands, characterized by climate variability and population growth, is difficult. Exploration and exploitation of groundwater, due to inadequate surface water is very costly. This study employed the analytic hierarchy process (AHP) and GIS to identify groundwater potential (GWP) areas in a semi-arid region of Nigeria. Land-use-land-cover, drainage density, slope, rainfall, static water level, soil, lithology, and aquifer were selected for GWP analysis. Parameter weights were determined using AHP and ranked based on their contribution to GWP by experts. The parameters were then integrated using the weighted overlay tool in ArcGIS 10.5 to produce a GWP map of the study area. Borehole yield data from 245 wells were collected to determine the model accuracy and model validation. Results classified the study area into very high GWP (1.9%), high GWP (8.8%), moderate GWP (62%), low GWP (20.70%) and very low GWP (6.6%). Areas with better GWP include Gurun, Dugol, Zago, Kumbo, Dukku, Doguwa, Riruwai, Dambazau, etc. Moderate GWP areas are widely spread across the state while areas with poor GWP include Sharawa, Kadewa, Koya, Dagar, Jigilawa, Galwanga, Yanganau, Kunchi, Tofa, Tsanyawa, etc. Validation of the AHP model with borehole yield data shows a correlation coefficient of 71.3% giving a good prediction. AHP and GIS can be used to successfully map GWP areas which could serve as an exploration guide for sustainable management of groundwater resources in semi-arid areas.

1 Introduction

Socio-economic activities, sustainability, and wellbeing of the human population rely on freshwater supply (Griggs et al., 2013). Water security is a serious issue that has hampered the attainment of the United Nation's Sustainable Development Goals (UN-SDGs) in many countries (van Vliet et al., 2021; Zeng et al., 2013). Statistics have shown that 5.52 billion people from 186 countries face water insecurity today (Nkatha, 2024). Of this number, 40% live in Sub-Saharan Africa (UNICEF and WHO, 2019). Jones et al. (2024) indicated that 47% of the world's population is exposed to water scarcity while 47% is affected by a lack of clean water at least 1 month per year. Li et al. (2024) show that over half of China's population face water scarcity for at least 1 month annually. Numerous inter-state conflicts over transboundary rivers have been reported (CNA, 2017). For several years, concerted efforts have been made all over the world for the efficient conservation and management of surface water (Pirone et al., 2024; Errico et al., 2019). However, the scarcity of surface water sources, together with a decline in the quality and quantity of such resources in arid and semi-arid environments intensified reliance on groundwater for domestic and agricultural use (Akujieze et al., 2003). There is also the problem of surface water pollution due to anthropogenic activities and lack of wastewater treatment (Dan'azumi and Bichi, 2010). By 2030, about 250 million people in Africa may experience high water stress (Groth et al., 2020; Mpandeli et al., 2020). The increasing level of freshwater demand due to the ever-growing population necessitates more attention on groundwater sources in many communities (Roy et al., 2020; Tarhule, 2007).

Ground-based geophysical surveys give precise information on the groundwater potential (GWP) of an area, but the method is expensive and time-consuming for a large area. This calls for a cost-effective multi-criteria decision-making approach in conjunction with remote sensing technology and geographic information system (GIS) for the identification of potential groundwater resource areas that could pave the way for effective and sustainable groundwater exploration and exploitation initiatives (Abdullateef et al., 2021). Remote sensing has been employed by many researchers in the prediction of natural changes on the earth's surface (Mohammad et al., 2023). Due to the importance of groundwater, researchers have worked a lot and proposed other alternative methods to groundwater exploration. Some examples include the works of Feng et al. (2024), Guo et al. (2023), Pharm et al. (2022), and Azari et al. (2021) among many others. Groundwater is normally recharged from surface water and therefore has high sensitivity to the presence of surface water sources (Crimaldi and Lama, 2021; Box et al., 2021; Lama and Crimaldi, 2021). Groundwater occurrence and distribution in a geographical location depend on the anthropogenic, physiographic, and climatic factors affecting the hydrological conditions of the area. Analyzing the relationship and overall influence of such factors on groundwater availability is essential for the effective prediction of the GWP of an area (Rahmati et al., 2015).

In their quest for a suitable prediction methodology of potential groundwater areas through modeling the effects of physiographic variables on hydrologic parameters to achieve sustainable groundwater management, hydrogeologists found the method of analytic hierarchy process (AHP) as one of the multi-criteria decision analysis models useful for effective groundwater management (Jha et al., 2010; Madrucci et al., 2008). The method provides a means for dealing with complex spatial decision problems by decomposing the spatial decision problem into a hierarchy of sub-problems for easy comprehension and subjective evaluation (Cabrera and Lee, 2019). The AHP is an Eigenvalue approach to pair-wise comparisons to calibrate the numeric scale for the measurement of quantitative as well as qualitative performances. The scale covers the entire spectrum of comparison from 1/9 for “least important than”, to 1 for “equal important than”, and to 9 for “strongly more important than” (Vaidya and Kumar, 2006). The method is one of the foremost decision-making models that is being applied to solve a countless number of real-world problems (Brunelli, 2015).

Nithya et al. (2019) studied the influence of geology, lineaments, geomorphology, slope, drainage density, soil, and rainfall on the GWP of Chittar Basin India, using GIS-based AHP. Results were validated using the groundwater yield of 24 open wells. The GWP map classified the areas into very good, good, medium, poor, and very poor GWP. Ifediegwu et al. (2019) used integrated remote sensing (RS), GIS, and AHP to study the influence of eight thematic maps (geology, rainfall, geomorphology, slope, drainage density, soil, land use land cover (LULC) and lineament density) on GWP in Lafia, Nigeria. Validation was done using data from 50 boreholes. Results classified 19.3, 12.9, 57.8, and 10% of the study area into good, moderate, poor, and very poor GWP areas. Kamaraj et al. (2023) integrated remote sensing and GIS to determine the effect of 15 parameters (i.e. geology, geomorphology, lineament density, topsoil resistivity and thickness, weathered zone resistivity and thickness, first fractured resistivity and thickness, second fractured resistivity and thickness, slope, LULC, drainage density and rainfall) on GWP of Mettur taluk, Salem district and Tamil Nadu, India. Results showed that topsoil thickness, pediment, lithology, slope type, and rainfall as the predominant factors influencing groundwater potential. Ally et al. (2024) combined seven thematic map layers of lithology, soil types, lineament, magnetic intensity, slope, drainage density, and elevation to develop a GWP zone map of Mpwapwa District, Tanzania. The resulting GWP zone was validated using the area under the curve and overlaying method. It was shown that 19% of the area was classified as very good, 31% as good, 28% as moderate, 22% as poor, and 2% as very poor GWP zones.

Other models used by researchers, in combination with GIS, include those for groundwater vulnerability assessment such as the DRASTIC model. DRASTIC represents seven (7) parameters used to describe the influence of geology and hydrogeology of an area in the model: D (depth of water), R (net recharge), A (aquifer media), S (soil media), T (topography), I (impact of the vadose zone), and C (hydraulic conductivity) (Fritch et al., 2000; Hamza et al., 2007; Jamrah et al., 2008).

Research has also been carried out to compare AHP with other approaches. Razandi et al. (2015) compared the use of AHP, frequency ratio, and certainty factor to map the GWP of Varamin Plain, Tehran Iran. Receiver operating characteristic was used to determine the accuracy of the GWP maps and results indicated that the frequency ratio outperformed both the AHP and certainty factor methods. Kaur et al. (2019) used remote sensing and GIS to compare AHP with Catastrophe theory for the demarcation of GWP zones in the Panipat district, India. Results showed that the percentage of area covered by each model is almost the same, thus the two models can be used for delineation of GWP areas. Shekar and Mathew (2023) combined slope, drainage density, rainfall, geomorphology, LULC, curvature, soil, topographic wetness index, distance from the river, and elevation as thematic layers and used AHP and fuzzy-AHP in a GIS environment to assess GWP zones in Murredu river basin, India. The zones were classified as poor, moderate, and good GWP areas.

AHP has been used, in GIS environments, by many scholars in the prediction of GWP areas to explore groundwater resources (Aluko and Igwe, 2017; Fashae et al., 2014; Ifediegwu et al., 2019; Igwe et al., 2020; Pinto et al., 2017; Rahmati et al., 2015; Roy et al., 2020; Elsebaie and Kawara, 2024). The approach has proven to be a reliable means of facilitating, interpreting, analyzing large volumes of diverse dataset which are then modeled through analytic procedure to produce useful information for use by authorities concerned (Guru et al., 2017). For this purpose, the present study employed AHP, using remote sensing and GIS, to integrate hydro-geological and climatic data to assess and map GWP areas which could serve as an exploration/exploitation guide for efficient and sustainable management of groundwater resources in Sub-Saharan Africa and other places with similar geology. The use of AHP in combination with remote sensing and GIS is novel in this part of the world as information is scarce in sub-Saharan Africa. The research will provide policymakers on the best way to sustainably manage the groundwater in the similar areas.

2 Materials and methods

Figure 1 shows the methodology flowchart, which will be explained in detail in the following subsections.

Figure 1

Figure 1. Flowchart of the methodology used for GWP mapping using the AHP.

2.1 Study area

The study area is located in Kano state, northern part of Nigeria, West Africa. The area lies between latitudes 10°23′ 40^′′ and 12°34′24^′′ North, longitudes 7°41′ 15^′′ and 9°21′ 21^′′ East (Figure 2). Mean annual rainfall is 635 mm in the north and 1,000 mm in the south and occurs between May and October (Hamza et al., 2017). The total areal coverage of Kano state is estimated at 20,131 km² which is mostly underlain by a crystalline basement rock and the remaining area is comprised of a sedimentary formation (Bala et al., 2011) (Supplementary Figure 1). The Northern Nigerian basement complex comprises migmatites and high-grade gneisses; the younger metasediments of upper proterozoic age and the older granite series (McCurry, 1989). The sedimentary formation consists largely of unconsolidated sandy sediments. Aquifers exist in three known layers in which the two top layers are accessible to borehole exploitation (Tukur et al., 2018). Hazell et al. (1988) also report the occurrence of rocks of the younger granites series as well as volcanics, and occasional younger dykes and flows. The lithology of the area shows three layers consisting of a topsoil layer with a thickness varying from 1.12 to 11.5 m, a weathered layer with a thickness varying from 5.29 to 54.34 m, and a fractured/fresh basement layer with a thickness varying from 23.18 to 68.60 m (Tahir et al., 2014).

Figure 2

Figure 2. Map of Kano state showing borehole locations and LGAs.

Kano state is the most populous state in Nigeria with a population density of 764/km². The 2023 population of the state is about 15,462,200 people with an annual growth rate of 3.2% (NPC, 2023). During the 2010–2013 period, there was a steady annual decrease of groundwater level. Groundwater beneath the floodplains dropped from 9,000 to 5,000 million cubic meters from 1964 to 1987 in the Chad Formation area of the region (Tukur et al., 2018). Surface water is not readily available to abstract, treat, and supply to communities which puts more pressure on groundwater sources. There is indiscriminate drilling of boreholes in the state and this results in the decline of water tables as more boreholes and wells dry up. This underscores the need to have an assessment of the groundwater with a view to sustainably manage it.

2.2 Data collection

The administrative boundary map, in shape file format, downloaded from DIVA-GIS (http://www.divagis.com), was employed for the generation of study area extent. Satellite imagery of LandSat 8 OLI and Shuttle Radar Topographical Mission Digital Elevation Model (SRTM DEM) both having 30 m spatial resolution were obtained from the United States Geological Survey website (http://www.glovis.usgs.com). Two hundred and forty-five (245) sets of borehole log data spread across the study area, were obtained from the archives of the Kano State Agricultural and Rural Development Authority (KNARDA) (1989). The borehole log data was collected by Wardrop Engineering Inc., the company that was contracted to carry out the drilling exercise. The borehole log data was used to generate a hydrogeological profile of the study area. The boreholes were ranked according to their yield in the order W1 to W245 with W1 having the lowest yield and W245 the highest. Also, rainfall data from nine (9) meteorological stations was obtained from the Kano State Water Board.

2.3 Data processing

For the remotely sensed data, the administrative boundary data was processed in an ArcGIS environment to mask Kano State as shown in Figure 2. Landsat 8 OLI images were clipped to the study area and ERDAS 9.0 was used for the satellite image processing. Land-use-land-cover (LULC) was interpreted using a visual interpretation technique and supervised classification of maximum likelihood classification was carried out for the final LULC map. For this study slope steepness and stream network information were deduced from SRTM DEM having 30 m spatial resolution, while the stream network information was consecutively processed to produce flow direction information for the surface drainage, flow accumulation information, stream order information, and finally, generating drainage density map for the study area.

The rainfall distribution map of the area under study was produced from the rainfall data of nine meteorological stations across the study area ie (Challawa, Karaye, Gajale, Riruwai, Wudil, Ranka, Joda, Wak, and BUK) using inverse distance weighting (IDW) interpolation method. While available information on static water level, soil, lithology, and aquifer, obtained from the KNARDA, was used to produce the static water level, soil, lithology, and aquifer maps of the study area respectively.

2.4 Analytic hierarchy process (AHP)

The AHP is a multi-criteria decision-making process involving experts ranking the relative importance of some chosen parameters. Structured interviews were done with 25 experts from universities and water resource institutes within the study region in the month of March, 2023. The background of experts covers the field of hydrogeology and water resources engineering. The questionnaire, shown in Supplementary Table 1 was used to identify the relative importance of all selected criteria. This questionnaire was based on a scale of 1–9 (Supplementary Table 2) for the experts to assess the relative importance of each individual criteria.

The steps involved in AHP are as follows:

Step 1: This step involves the identification of thematic layers. In this work, eight thematic layers of LULC, drainage density, slope, rainfall, static water level, soil, lithology, and aquifer were chosen.

Step 2: The experts' opinion was used to generate a pairwise comparison matrix (Table 1) based on their relative importance using Saaty's scale. Maps of the parameters were classified on a uniform rank of 1–5, where a scale of 1 denotes very low, 2 low, 3 implies moderate, 4 represents high and 5 denotes very high GWP (Mukherjee et al., 2012; Roy et al., 2020).

Table 1

Table 1. AHP model pair wise comparison matrix among parameters.

Step 3: Computations of the normalized weights utilizing the criteria's geometric mean (G_m) as shown in Equation 1. The normalized weights are presented in Table 2.

\begin{array}{l} W_{n} = \frac{G_{m}}{\sum_{i = 1}^{i = n} G_{m}} & (1) \end{array}

Table 2

Table 2. Normalized pairwise comparison matrix and weights of each parameter.

where Wn = Eigenvector of the matrix.

Step 4: The principal eigenvalue and Consistency Index (CI) were calculated to capture the uncertainty in experts' judgments using Equation 2:

\begin{array}{l} C I = \frac{λ_{\max} - n}{n - 1} & (2) \end{array}

where λ_max = largest eigenvalue from the pairwise comparison matrix and = number of classes. The consistency of the pairwise comparison matrix was measured using a Consistency Ratio (CR) given by Equation 3:

\begin{array}{l} C R = \frac{C I}{R I} & (3) \end{array}

where RI = random consistency index = 1.41 when n = 8 (Saaty, 1980).

Step 5: The resulting thematic maps of LULC, drainage density, slope, rainfall, static water level, soil, lithology, and aquifer were integrated according to Equation 4 using the weighted overlay method in ArcGIS 10.5 to generate an index value signifying the level of GWP per each cell.

\begin{array}{l} G W P I = \sum_{i = 1}^{n} W_{i} X_{i} & (4) \end{array}

where GWPI = the GWP index, W_i = the determined weight of each thematic layer. X_i = the ranks for the classes within each thematic layer.

Model validation is done using various approaches such as coefficient of determination (R²), percentage bias, Nash-Sutcliffe efficiency, and correlation coefficient (r) (Opere et al., 2022; Azari and Asadi, 2017; Moriasi et al., 2007). The prediction accuracy of this model was determined and the proposed GWP map was validated with recorded borehole yield data using the Pearson correlation coefficient (r) and to serve as an easy guide for the assessment of groundwater availability within the study area (Equation 5).

\begin{array}{l} r = \frac{\sum (x_{i} - \bar{x}) (y_{i} - \bar{y})}{\sqrt{\sum {(x_{i} - \bar{x})}^{2} \sum {(y_{i} - \bar{y})}^{2}}} & (5) \end{array}

where x_i is the respective borehole yield value at a particular point, $\bar{x}$ is the mean borehole yield, y_i is the GWP index value at that point and $\bar{y}$ is the mean of the GWP index values. The R² value was determined using Equation 6:

\begin{array}{l} R^{2} = {(r)}^{2} & (6) \end{array}

R values may range between −1 to +1. For r values between 0 and ±0.3, there is a weak relationship, ±0.3 to ±0.7 indicate a moderate relationship. Values between ±0.7 to ±1.0 indicate a strong linear relationship (Ratner, 2009; Schober et al., 2018). R² values range between 0 and 1. Values between 0 to 0.2 indicate no relationship, 0.2 to 0.4 indicate a moderate relationship, 0.4 to 0.6 indicate a strong relationship, 0.6 to 0.8 indicate a very strong relationship, and values above 0.8 indicate a perfect relationship.

3 Results

3.1 LULC

LULC of an area controls hydrological processes of evapotranspiration, infiltration and surface runoff, which largely govern the occurrence and distribution of groundwater resources (Kaliraj et al., 2014). The LULC map of the study area (Figure 3) shows water bodies, trees, grassland, vegetation agriculture, and shrubs covering a total area of 317 km² (1.58%), 675.42 km² (3.36%), 2.68 km² (0.0134%), 13.90 km² (0.070%), 909 km² (4.5%) and 17,593 km² (87.39%) respectively. These dominant land uses promote infiltration which leads to high groundwater prospects. The built-up area and bare ground occupy only 587 km² (2.92%) and 33 km² (0.15%) respectively.

Figure 3

Figure 3. Map showing land-use-land-cover of the study area.

3.2 Drainage density

Drainage density of an area defines the sum of the drainage channel lengths per unit area. Drainage basins having high drainage density results in low infiltration within its subsurface formation and hence, low groundwater prospect (Singh et al., 2013). In the study area, the high and very high drainage density areas constitute 10,390 km² (51.60%), moderate 7,828 km² (38.90%) while low and very low drainage density covered only 1,913 km² (9.50%) of the study area (Figure 4). This low to very low drainage density zones implies high infiltration and recharge potentials which is a function of high groundwater prospect (Roy et al., 2020).

Figure 4

Figure 4. Map showing the drainage density of the study area.

3.3 Slope

The slope is an aspect of geomorphologic features. Its nature along with other geomorphic features play a significant role in determining infiltration and potential groundwater recharge in an area. The slope of the study area as illustrated in Figure 5 revealed that about 18,007 km² (89.50%) of the area is covered by a slope of < 5 degrees signifying a nearly level and gentle surface which gives a high infiltration rate and high probability of groundwater prospect. 879 km² (9.30%) is covered by (5–8) degrees moderately sloping, 195 km² (0.95%) is covered by (9–20) degrees slightly steep sloping while 50 km² (0.25%) of the area is covered by >20 degrees steep slope leading to less rainfall/runoff infiltration and less probability of groundwater prospect (Jaiswal et al., 2003).

Figure 5

Figure 5. Map showing the slope of the study area.

3.4 Rainfall

Rainfall is a meteorological factor that contributes immensely to groundwater recharge. Understanding the nature and characteristics of rainfall of an area helps in predicting its effects on evapotranspiration, infiltration and surface runoff. For hydrological analysis, areal distribution of rainfall is required to create potential groundwater areas (Fashae et al., 2014). The distribution of rainfall in the study area ranges from 629 mm to 1,510 mm with reference evapotranspiration of 5.88 mm/day. The aridity index of Kano is 0.49 suggesting a seasonally semi-arid climate with a mean annual rainfall decreasing toward the north (Ogunrinde et al., 2019; Hamza et al., 2019). The rainfall map (Figure 6) reveals that about 1,043 km² (5.18%) received a high amount of rainfall which signifies good GWP, 276 km² (1.37%) moderate, while 18,812 km² (93.45%) received a low amount of rainfall suggesting poor GWP.

Figure 6

Figure 6. Map showing the rainfall distribution of the study area.

3.5 Static water level

Static water level is a measure of the distance from the ground surface to the water level and a parameter that determine the potential distance for water to travel to the aquifer. Variation in static water level within the study area shows a change ranging from 1.4-9.6 m covering 6358 km² (31.6%), as very high, 9.7–18 m covering 9,103 km² (45.2%) as high, 19–26 m covering 4,187 km² (20.8%) as moderate, while 27–34 m covering 463 km² (2.30%) and 35–43 m covering 20 km² (0.10%) as low and very low groundwater prospective areas respectively (Figure 7).

Figure 7

Figure 7. Map showing the static water level of the study area.

3.6 Soil

Soil is an influencing factor that facilitates infiltration of rainfall and represents surface features that control the amount of recharge into the saturated zone. The depth of the soil ranges from the surface up to 10 m deep. The soil types in Figure 8 include sand, sandy loam and peat covering 3,866 km² (19.18%) which allow water to infiltrate easily due to high permeability suggesting high groundwater prospect area, loamy soil covers an area of 8,968 km² (44.6%) and non-aggregated clay, clay loam and silt covered 7,297 km² (36.22%) which imply limited infiltration because of low permeability and hence, low groundwater prospect (Fashae et al., 2014).

Figure 8

Figure 8. Map of the study area showing soil.

3.7 Lithology

The lithological unit plays an important role in transmitting the water to the lower layer (aquifer media). This unsaturated zone of the study area (Figure 9) is underlain by basement complex rocks and sedimentary formation. Only 824 km² (4.1%) of the study area is covered by sandstone which allows high infiltration due to its high porosity hence, suggesting high groundwater availability. Metamorphic/igneous and shale formations covered 12,597 km² (62.6%) giving moderate infiltration and silt/clay covered 6,710 km² (33.3%) allowing low infiltration suggesting a low probability of groundwater prospect (Ifediegwu et al., 2019).

Figure 9

Figure 9. Map of the study area showing lithology.

3.8 Aquifer

Aquifer properties control the rate at which groundwater flows within an aquifer formation. Figure 10 shows that the aquifer formation in the study area comprises thin-bedded sand and sand/gravel formations occupying 2,189 km² (11%) and 613 km² (3%) respectively, suggesting high groundwater prospects. The metamorphic/igneous and weathered rocks occupy 5,647 km² (28%) and 11,682 km² (58%) suggesting moderate GWP.

Figure 10

Figure 10. Map of the study area showing the aquifer.

3.9 GWP map

The GWP map in Figure 11 was generated according to Equation 4 by weighted overlay analysis of the determined weights of each of the groundwater controlling parameters. The map was assigned ranks for the sub-class of each parameter (Table 3). The factors were ranked on a scale of 1–5, where a scale of 1 denotes very low, 2 low, 3 implies moderate, 4 represents high and 5 denotes excellent GWP as adopted by Jha et al. (2010), Mukherjee et al. (2012), and Roy et al. (2020). The GWP map was classified into very low covering 1,320 km² (6.60%), low 4164 km² (20.70%), moderate 12,482 km² (62.0%), high 1,783 km² (8.80%), and very high covering 382 km² (1.90%) of the study area (Figure 11).

Figure 11

Figure 11. Map of the study area showing the GWP.

Table 3

Table 3. Ranking of factors on a scale of 1–5.

The classified boreholes yield data in Table 4 were superimposed on the GWP map which was obtained using the RS-GIS and AHP methods. The results show that out of 80 boreholes with (ID No W1 to W80) classified as low-yielding wells (yield < 50 l/min), 67 fall within very low to low GWP categories representing 83.8% accuracy. Out of the 129 wells with (ID No W81 to W209) classified as moderate yielding wells (with yield between 50 l/min to 100 l/min), 82 fall within the moderate GWP category representing 63.6% and likewise, out of the 36 wells with (ID No W210 to W245) classified as high yielding wells (with yield > 100 l/min), 28 fall within the high and very high GWP representing 77.8% accuracy. The overall accuracy is thus 74.4 percent (Figure 11). With a good correlation coefficient of 71.3 % and prediction accuracy of 74.4%, it is evident that AHP can be used to predict the GWP of areas as a surrogate measure for borehole yield.

Table 4

Table 4. Classification of boreholes yield of the study area in comparison with (Fashae et al., 2014).

3.10 Model validation

Validation is the most important process of a model without which models lack scientific significance (Chung and Fabbri, 2003). For validation, the Pearson Correlation Coefficient was employed to compare the recorded borehole yield data with the GWP index value obtained by the AHP model. The plot assessment shows a correlation coefficient of 0.713 indicating a strong prediction. Also, the R² value of 0.508 indicates a strong relationship between borehole yield and the GWP index (Ratner, 2009; Schober et al., 2018) (Figure 12).

Figure 12

Figure 12. GWP index and yield relationship.

4 Discussion

Globally, the problem of stress on freshwater supply is a well-documented issue. This problem is exacerbated by climate change which manifests itself in drought in some parts of the world. Highly populated areas, such as Kano, become more vulnerable arising from the over-abstraction of water sources due to high water demand from the high population of about 15,462,200 persons (NPC, 2023). Surface water pollution and grossly insufficient municipal water supply have led to the demand for groundwater in the state (Akujieze et al., 2003; Tukur et al., 2018). The United Nations Sustainable Development Goal No. 6 (SDG 6) attempts to address this issue and Nigeria is not on track to achieve this by 2030 as only 29% of the population uses safely managed drinking water sources (UN World Water Development Report, 2022). Other targets related to SDG 6 are also below 50% which is far from the expectations. The country has to fast-track the implementation of policies to achieve this aim.

The geology of the study area is mostly comprised of the crystalline basement complex rock and the remaining is sedimentary formation. Generally, water in the basement complex area is higher relative to the water table in the Chad formation. Mustapha et al. (2014) have pointed out the basement complex areas of Kano have water levels generally varying from 6 m to 25 m which rarely reach up to 50 m in some places. In contrast, the Chad Formation has a water table ranging from 20 m to 50 m. A sharp decline in groundwater levels calls for research on groundwater sustainability. AHP was integrated into RS and GIS to delineate and map GWP areas. Eight thematic layers affecting groundwater recharge potential including LULC, drainage density, slope, rainfall, static water level, soil, lithology, and aquifer were chosen in this research.

Landsat-5 Thematic Mapper I imageries were used in groundwater exploration in the basement complex rocks of the Kano, Zaria, and Kaduna areas. It was found that areas with high fracture density have high groundwater potential (Bala, 2001). Olorunfemi and Fasuyi (1993) delineated the aquifer types in the study area. These aquifer types include; weathered layer aquifer, weathered/fractured or partly weathered aquifer, and fractured aquifer. Bala et al. (2011) examined the regolith aquifers derived from different bedrock types in the basement complex of Kano using the information on the depth of borehole, static water level, yield, and drawdown of 259 boreholes covering different rock types. Their result shows that the mean depth of the borehole varies from about 37 m to 48 m in rocks of the younger granites and the migmatites-gneiss complex and schists, respectively. Isa (1984) investigated the hydraulic properties of the basement complex and Chad formation aquifers of Kano State based on pumping tests of selected boreholes. In the basement complex areas, an average transmissivity was 12.32 m²/day, hydraulic conductivity was 0.33 m/day and specific capacity was 0.36 m³/m of drawdown. Strong variation in the water levels is attributed to topography, overburden thickness, and geology. Aquifers are found in the weathered layer where it is extensively thick while the bedrock also serves as an aquifer where it is extensively fractured (Tahir et al., 2014). The aquifers comprised both confined and unconfined found in both the weathered and the fractured rocks (Yola and Ismail, 2012; Ismail and Yola, 2012; Idris et al., 2020; Yelwa et al., 2015).

Results of the spatial analysis show that better groundwater prospective areas occupied a total area of 2,165 km² (10.70%) and were mostly situated in Gurun, Dugol, Zago, Kumbo in the north and Dukku, Doguwa, Riruwai, Dambazau in the southern parts of Kano State. These are mainly attributed to the nature of the topography, drainage density, and rainfall and these areas could be suitable for groundwater development for agricultural utilization. These areas were represented as W210-W245. Moderate GWP areas are widely distributed across the study area and cover 12,482 km² (62%) of the state and could be suitable for groundwater development for domestic use. These areas were represented as W81-W209. Meanwhile, poor GWP areas covered 5,484 km² (27.30%) and are concentrated mostly in areas having high drainage density and low rainfall at central and southeastern parts of Kano state. The poor GWP include Sharawa, Kadewa, Koya, Dagar, Jigilawa, Galwanga, Yanganau, Zuwo, Garji Kadaye, Kankarawa, Kunchi, Tsanyawa, Jobe, Tofa, Kabo, etc. These areas were represented as W1-W80 (Figure 11, Supplementary Figure 2). These poor GWP areas could not be sufficient for groundwater development for commercial agriculture hence the need for surface water infrastructure to augment the existing water supply system. For sustainability, efforts should be stepped up to improve water supply, using surface water sources, in areas close to existing surface waters. This will go a long way in relieving the current pressure on groundwater.

5 Conclusion

Groundwater sources are known to be reliable in terms of quantity and quality. This is so particularly in arid areas where surface water is ephemeral. Water security issues are compounded in developing countries due to insufficient funds and lack of political will and technical know-how toward the conservation of the available surface water resources. Identification of GWP areas in arid environments was achieved through the use of an expert-based multi-criteria evaluation approach of AHP in a GIS environment. The result shows rainfall (23.9%) and slope (19.4%) as the most important factors contributing to GWP while LULC (4.99%) and soil (5.03%) exert the least significant impact. However, the developed model categorized the study area into very low 1,320 km² (6.60%), low 4,164 km² (20.70%), moderate 12,482 km² (62.0%), high 1,783 km² (8.80%), and very high 382 km² (1.90%) groundwater prospective areas. Areas with better GWP include Gurun, Dugol, Zago, Kumbo, Dukku, Doguwa, Riruwai, Dambazau, etc. Moderate GWP areas are widely spread across the state while areas with poor GWP include Sharawa, Kadewa, Koya, Dagar, Jigilawa, Galwanga, Yanganau, Kunchi, Tsanyawa, Jobe, Tofa, Kabo, etc (Figure 11, Supplementary Figure 2). Consequently, the AHP model was validated with recorded borehole yield data to achieve a correlation coefficient of 71.3% and prediction accuracy of 74.4%. With fairly good model validation results, it is evident that the geospatial technology of RS-GIS and AHP technique can be employed to successfully map groundwater prospective areas which could serve as an exploration/exploitation guide for efficient and sustainable management of groundwater. In addition, for the long-term sustainability of water resources in the study area, an updated RS-GIS and AHP using adequate inventory data is recommended as well as the development of more surface water infrastructure in poor GWP areas to curtail the prevailing groundwater development in Nigeria and other regions with similar characteristics.

Data availability statement

The data analyzed in this study is subject to the following licenses/restrictions: the datasets are not publicly available. It was given to us on research request. Requests to access these datasets should be directed to Kano State Agricultural and Rural Development Authority. https://knarda.org/contact/.

Ethics statement

Ethical review and approval was not required for the study on human participants in accordance with the local legislation and institutional requirements. Written informed consent from the (patients/participants OR patients/participants legal guardian/next of kin) was not required to participate in this study in accordance with the national legislation and the institutional requirements.

Author contributions

AS: Conceptualization, Formal analysis, Investigation, Methodology, Software, Validation, Visualization, Writing – original draft, Writing – review & editing. AA: Funding acquisition, Project administration, Visualization, Writing – original draft, Writing – review & editing. SD: Formal analysis, Investigation, Methodology, Project administration, Supervision, Writing – original draft, Writing – review & editing. SA: Formal analysis, Software, Validation, Writing – original draft, Writing – review & editing. SH: Data curation, Resources, Visualization, Writing – review & editing.

Funding

The author(s) declare financial support was received for the research, authorship, and/or publication of this article. This work was supported by Prince Sattam bin Abdulaziz University (Project Number: PSAU/2024/R/1445).

Acknowledgments

The authors extend their appreciation to Prince Sattam bin Abdulaziz University for funding this research work through the project number (PSAU/2024/R/1445).

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher's note

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Supplementary material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/frwa.2024.1484753/full#supplementary-material

References

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