Abstract
Shortage of potable water is a global problem, and this problem can be met by searching new areas where groundwater is available. GIS is an effective and necessary tool to identify groundwater potential zones in an area. In the present study, groundwater potential zones (GWPZs) were identified in the Kangsabati River basin of east India having an area of about 6488 km2 using multi-criteria decision analysis (MCDA) and analytical hierarchy process (AHP). The criteria like geology, geomorphology, elevation, slope, drainage, lineament, curvature, topographic wetness, land use/land cover, and soil were extracted from satellite data and the weights for each parameter and its sub-parameters were assigned through analytical hierarchy process based on their respective relevance as influencing factors for groundwater recharge. Very low, low, moderate, high, and very high groundwater potentiality represent 28.93%, 30.56%, 19.75%, 14.62%, and 6.11% area, respectively. The low-lying flat plains of the southeastern section, as well as the centrally located dam, are ideal for groundwater recharge, while the upland plain of the northwestern part, with its hard rock terrain, is less so. This outcome has been verified using pre-monsoon and post-monsoon groundwater depth data, indicating that the strategy is most appropriate for this region. Thus, the groundwater potential zone maps remain very useful for conducting extensive ground-based hydrogeological studies that facilitate the identification of suitable bore well/dug well sites.
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Introduction
Water is an important life-giving resource on the planet. It is the basic material that is required for life to exist. It has played a vital role in the formation of society since the dawn of human civilization. Water is widely dispersed on the planet, yet its quality and quantity fluctuate over time and location. Only 3% of the overall water resource is fresh, with the majority of freshwater being trapped as ice. Approximately 34% of the total water resource appears in the form of groundwater. Lakes and rivers contain less than 1% of all freshwater (Holden 2014). Freshwater allocation in the world is 2.50 percent, with groundwater accounting for only 1.69 percent (Te Chow 2008). Groundwater provides 34 percent of the world’s freshwater sources to human society (Dar et al. 2010; Ghosh et al. 2016; Murmu et al. 2019). It is the surface water that seeps into the ground through the processes called infiltration and percolation. Groundwater is a primary hot spot for industries, communities, and agricultural consumption on the planet. The amount of groundwater on earth is assessed at in excess of 50 million cu. km. Of this, 4 M km3 is considered as a sensible amount of crisp water that could be misused, which bars water that will not deplete from little pore spaces, saline water, and water lying somewhere down in restricted aquifers.
For domestic purposes, about 90 and 50% of rural and urban Indians, respectively, rely on groundwater (Central Ground Water Board 2014; Das et al. 2018). Groundwater is under stress as a result of expanding population, urbanization, agricultural, and industrial activities, and it is difficult to meet these needs with current groundwater resources (Saha, 2017). The demand for water is quickly increasing as a result of rapid urbanization and extraordinary population expansion (Choudhary et al. 1996). Groundwater is the greatest exploitable supply of freshwater, accounting for around 34% of the world’s freshwater (Sharma and Kujur, 2012; Neelakantan and Yuvaraj, 2012). Due to rising industrialization and population expansion, demand for this natural resource is escalating, resulting in scarcity in some areas, and it plays a significant part in global climate change and meeting basic needs. Various industries, particularly agriculture, manufacturing, and energy, have seen remarkable progress in the previous few decades. This has led to growing demand for irrigation, domestic, and industrial needs (Singh et al. 2011).
Groundwater is a life-sustaining resource. The increasing demand for groundwater in India was observed during the 1970s as a major impact of the Green Revolution. Since the beginning of the Green Revolution, groundwater variations have been observed in various parts of India. Numerous states in India are experiencing a severe groundwater shortage, and various studies have been done to determine groundwater prospective zones. Groundwater prospective zones have been recovered with the aid of remote sensing data and a GIS technique in the states of Tamil Nadu, Karnataka, Uttar Pradesh, and a few other parts of India (Ramu et al. 2014; Ali et al. 2015; Pande et al. 2017; Das et al. 2018).
Groundwater is a valuable natural resource that plays a vital part in the economy. It is one of the primary sources of water for agricultural irrigation and human consumption. Around 43% of groundwater resources are mainly used for agricultural activities. It plays a very important role during the drier months where there is a little direct recharge from rainfall mainly in the monsoonal countries of southeast Asia. It plays an important role in the wildlife and plants to survive in those high temperatures. Groundwater also plays an important role in increasing the water levels in rivers. Because of its storage underneath the surface, it is less contaminated with the pollution and hence it does not require large investments in treatment. Groundwater recharge, also known as deep percolation, is a hydrologic process in which water travels downward from the surface to the ground, with two types of recharge: natural and artificial. Various methods are available to find groundwater recharge potential zones, which are a) geological technique, b) hydrogeological technique, c) geophysical technique, and d) remote sensing technique (Adhikary et al. 2015). Among them, remote sensing technique is the best way as other techniques require physical appearance at the study area and require so much knowledge to adapt them.
Many elements, including geology, geomorphology, drainage, slope, depth of weathering, existence of fractures, surface water bodies, canals, and irrigated crops, all influence groundwater potential in a specific location (Jain,1998; Nag and Ghosh, 2012). When the groundwater quality deteriorates, it might be due to the cumulative effect of two or many factors. To understand the cause of deterioration of overall groundwater quality, all these factors need to be analyzed. In certain places of India, limitations of this valuable resource have resulted from a lack of scientific planning and excessive consumption (Tiwari et al. 2017). The downward trend in water levels is quite worrying, as it will result in a long-term groundwater issue (Das and Mukhopadhyay, 2018). As a result, groundwater management is required for the restoration of this renewable resource. One of the essential components of this strategy implementation is to increase groundwater recharge (Baalousha et al. 2018). To get the effective recharge potential zones, multi-criteria decision analysis (MCDA) is a must where we can have a glimpse of influence of all the possible criteria on overall quality and recharge possibility.
Various models and quantitative methodologies (Prasad et al. 2008) like multi-influencing factor (Magesh et al. 2012), weighted overlay model (Sajikumar and Pulikkottil, 2013), logistic regression model (Pourtaghi and Pourghasemi, 2014), frequency ratio model (Razandi et al. 2015), and certainty factor model (Razandi et al. 2015) are being used globally to assess the groundwater potential zones. Out of these many models, the widely utilized tool for groundwater management is multi-criteria decision analysis (MCDA) (Madrucci et al. 2008; Jha et al. 2010; Rahmati et al. 2015). Saaty proposed the analytic hierarchy process (AHP) as a commonly used model of MCDA for solving socioeconomic decision-making concerns (Jhariya et al. 2016). Furthermore, the AHP model emphasizes not just individual elements, but groups of elements that are frequently required (Saaty 1999). The AHP model was used in this work to give relative importance to each groundwater prospecting parameter, which clarifies groundwater potential zone (Hajkowicz and Higgins 2008; Murthy and Mamo 2009; Chowdhury et al. 2009; Kaliraj et al. 2014). The major goal of this research is to identify groundwater prospective zones in the Kangsabati River basin using the AHP method and GIS approach, as well as the unification of eleven groundwater prospective criteria. Such quantitative research methods and the use of GIS techniques to analyze groundwater potential zones will aid planners and decision-makers in determining the best place for borehole drilling and long-term groundwater management.
Materials and methods
Location of the study area
The Kangsabati is a non-perennial river that flows through Purulia, Bankura, Paschim, and Purba Midnapore districts of West Bengal (India). It originates on the Chhotanagpur plateau edge in Jharkhand. The Kangsabati basin is a tropical plateau fringe basin that stretches from Jharkhand’s Chhotanagpur plateau to the Rupnarayan and Kheliaghai basins in the lower Gangetic Plain. This basin has a latitudinal extension of 21°30'N–23°30'N and a longitudinal extension of 85°45'E–88°15'E, covering an area of 9658 km2 (Bhattacharya 2018). In this study, a total area of 6487.90 km2 was used to assess the groundwater prospective zone (Fig. 1).
The top half of the plateau–plain sub-humid river basin is governed by rolling dissected plateau region, which is dominated by Pre-Cambrian granite, gneiss geological formation. The intermediate parts of the basin are dominated by primary and secondary laterite development, whereas the lower plain portions are dominated by alluvial deposition. Streamflow characteristics are dominated by lower water regimes and seasonal rainfall. It originates on the eastern Chhotanagpur plateau’s “Ajodhya Hill” and runs eastward through the plateau fringe region of West Bengal (Nag and Lahiri 2012). The fragmented Chhotanagpur plateau covers roughly 200 km in the top and middle parts of the basin, out of a total length of 465 km. According to research, the basin is in the latter stages of geomorphic evolution (Dutta and Roy 2012; Pan 2013).
Data procurement and use
To carry out the study and generate a groundwater potential map with appropriate accuracy, we procured Survey of India (SOI) Toposheet, accessible credible data and maps, rainfall data, remote sensing data, GIS software (ArcGIS, ERDAS IMAGINE, ENVI, PCI Geomatica, etc.), statistical software (SPSS), and GPS.
Preparation of thematic layers
The Kangsabati Basin’s GWPZ was defined using a variety of hydrogeological factors, including geology, geomorphology, elevation, slope, drainage density, lineament, curvature, topographic wetness index, soil, rainfall, and land use/land cover (Table 1). In the first step, all of the data were scanned and converted to raster format, as well as georeferenced to the universal transverse Mercator projection and datum WGS1984. On a 1:50,000 scale, a base map of the Kangsabati River basin was created using SOI topographical sheets (73I/10, 11, 12, 13, 73 J/9, 15, 73 N/2, 3, 4, 5, 7, 8). In ArcGIS, the SOI topographical maps were georeferenced using the WGS 84 datum and the UTM zone 45° N projection. Geology, geomorphology, land use/land cover, elevation, drainage density, slope, curvature, lineament, topographic wetness index, rainfall, and soil type were all addressed in this research as contributing factors for groundwater recharge. All contributing factors are classified after Jenks Natural Breaks classification system (Jenks 1967). The methodological flowchart in this study is presented in Fig. 2. Using the spatial analysis tool in ArcGIS, a slope and altitude map of the Kangsabati basin was constructed from ASTER GDEM (30 m). On a GIS platform, a land use and land cover (LULC) map of the basin was created using the maximum likelihood supervised classification approach. Landsat 8 satellite imageries were utilized to create the LULC map. Drainage networks were digitized from georeferenced topographical maps (73I/10, 11, 12, 13, 73 J/9, 15, 73 N/2, 3, 4, 5, 7, 8) and current drainage development from Google Earth images to create a drainage density map for the basin. ASTER DEM was chosen to create a stream network in the Kangsabati basin. Flow direction and flow accumulation raster computation sub-tools were utilized in ArcGIS spatial analysis tools to build stream networks. The raster streams were vectorized using conversion software (Raster to polyline). Finally, using the line density tool in the ArcGIS environment, a drainage density map of the Kangsabati basin was created. ENVI, PCI Geomatica, and ArcGIS tools were used to prepare geology and lineaments from a Geological Quadrangle Map with a scale of 1:2,50,000. BHUVAN thematic services, supplied by the National Remote Sensing Centre (NRSC), Hyderabad, were used to extract geomorphic traits and attributes of the basin. The soil map was created using NBSSLUP’s West Bengal soil map at a scale of 1:2,50,000, and the average yearly rainfall was calculated using University of East Anglia’s Climatic Research Unit (CRU)-UEA’s average rainfall data (2010–2019). Georeferenced SOI Toposheet of 1: 50,000 was resampled into 1:2,50,000 scale, and all the data layers were calibrated to bring in the same scale of 1:2,50,000.
Weightage analysis and normalization of AHP
The weightage of criterion and sub-criteria of the thematic layers is examined using the analytic hierarchy process (AHP). The AHP (Saaty 1980; Saaty and Vargas 1991) is a well-known means of multi-criteria technique which has been incorporated into the GIS-based suitability procedures (Jankowski and Richard, 1994; Marinoni, 2004). Each thematic map was resampled to a 30 m × 30 m pixel raster picture. AHP aids decision-making by combining various factors into a pair-wise comparison matrix. It uses a preference matrix to determine the requisite weighting factors, comparing all determined necessary criteria against each other with consistent preference factors, and then accumulates the weights of criterion map layers in a manner similar to weighted linear combination (WLC) approaches (Chen et al. 2010). The AHP approach can be used to arrange both quantitative (objective) and qualitative (subjective) information concerning decision-making analysis. Based on their relative relevance, each criterion was given a rank from 1 to 9 (Table 2). All of these elements were given a relative measure based on various criteria and preferences (1, equally important; 3, slightly important; 5, quite important; 7, extremely important; 9, absolutely important; 2, 4, 6, and 8 are intermediate values). The criteria were analyzed accordingly using the AHP matrix (Table 3, Table 4). The value “1” is organized diagonally in this matrix, which has an equal number of columns and rows. The relative relevance of two criteria is determined in each row. The first row of the matrix reflects the importance of a criterion in relation to 11 other criteria in the matrix’s column. The rows show the inverse value of each criterion and its relationship to other criteria. (Geology is more important than lineament density; so, geology has a value of 1 and lineament has a value of 2; thus, lineament density has a value of 1/2 in the following row.) To test whether or not the pair-wise comparisons were consistent, the consistency ratio (CR) was determined. The advantage of the AHP technique is that it accommodates for inconsistencies while still delivering a CR as a measure of consistency or inconsistency (Chen et al. 2010; Feizizadeh and Blaschke, 2013; Bera et al. 2019). When the consistency ratio is less than 0.10, a reasonable level of consistency can be assumed when computing the weights (Table 5) of the various criteria.
where \(\lambda_{max}\) is the principal eigenvalue; n stands for the number of considering factors; \(\lambda_{max} = \sum\) of the products between each element of the priority vector and column totals. Random consistency index (RI) was evaluated from a sample of “randomly generated reciprocal matrices” (Saaty 1990) (Table 6). The CR value of 0.078 suggested acceptable consistency for weight analysis and was appropriate for identifying the GPZ in this investigation.
The class that had the most suited, quality, and potential in each factor map was given the most weight. The class with the least potential, on the other hand, received the lowest weight. Groundwater recharge was used to offer a weight to each thematic data layer. The weight of the specified thematic map was computed using Satty’s analytical hierarchy technique and a pair-wise comparison matrix (Saaty 1990). On a scale of 0–9, classes of each factor were graded according to their relative importance on groundwater recharge. Furthermore, for groundwater potential zonation, a linear weightage sum combination approach was used by integrating the weight and ranking of the individual components and each class, respectively, in an RS-GIS environment.
where GWPI = groundwater potential index, GG = geology, LD = lineament density, GM = geomorphology, SL = slope, E = elevation, LULC = land use/land cover, DD = drainage density, RF = rainfall, S = soil type, C = curvature, TWI = topographic wetness index, and the subscripts “w” and “wi” refer to the normalized weight of a factor and the normalized weight of the individual class of a factor. Here, GWPI is a unit less amount to find out probable groundwater indexing in the area.
Results and discussion
Thematic layers for GWPZ
Geology
Because the geological setting of a place has such a big impact on surface runoff, infiltration, and seepage, the presence and dissemination of groundwater are primarily determined by it. Kuripal granite, Chhotanagpur gneiss complex, unclassified metamorphic, Lalgarh, Singhbhum, Dalma, Bhairabbanki, Panskura, Sijua, Arambagh, and present-day alluvial deposit are among the geological formations found in the basin (Fig. 3). The Chhotanagpur gneiss complex, Singhbhum, and unclassified metamorphic formations comprise the upper basin area, accounting for 30.78 percent, 30.48 percent, and 3.46 percent of the entire study area, correspondingly. The lower part is mainly dominated by Bhairabbanki, Panskura, Sijua, Arambagh, Lalgarh, and present-day alluvial deposit formation covering 0.37%, 2.87%, 12.46%, 4.37%, 11.34%, and 1.03% of the study area, respectively. From the Kangsabati River basin’s basement rock system, the oldest rock system consists of granite, granite gneiss, and mica schist. Unclassified crystalline minerals, predominantly gneiss, granite gneiss, and mica schist, cover the upper course of the Kangsabati basin. Alluvium and recent alluvial deposits have overlaid the laterite and meta-volcanic rock found in the middle and lower basins. Structural instabilities in the Kangsabati basin have taken the shape of lineament and joints. The main deformations extend from northeast to southwest. Weathered aquifers in the lower course of the alluvial plain and fractured aquifers in the upper basin granite gneiss geological formation were also found in the Kangsabati basin (Mahala 2020).
Lineament density
Lineaments are linear or curvilinear characteristics on the earth’s surface that are an apparent representation of an underpinning lithological structure including faults, fractures, and cleavages as observed by satellite imagery. The grid-based approach was used to calculate lineament density. It was defined as the total lineament length in the grid divided by the area of the grid (Edet et al. 1998).
where \(\sum {Li}\) is the total lineament length in the grid (km) and \(A\) is the grid area (km2).
Hard rock underpins the majority of the Kangsabati River basin, whereas lineaments generate secondary porosity and permeability, both of which are important for groundwater recharge. The primary fractures in the studied area run from north to south. The lineament density of the study area has been classified into five major classes, i.e., very low (0.0–0.19 km/km2), low (0.20–0.35 km/km2), moderately low (0.36–0.52 km/km2), high (0.53–0.70 km/km2), and very high (0.71.1.15 km/km2) (Fig. 4). Groundwater development has a lot of potential in areas where lineament density is high to very high.
Geomorphology
The geomorphology of a given area is thought to be an important factor in determining the groundwater potential zone. It also aids in the comprehension of groundwater presence, prospect, and mobility. On a hard rock terrain, tectonic activity and denudational processes are the primary determinants of geomorphological evolution. The Kangsabati River basin comprises the following geomorphic features: pediment–pediplain complex, low dissected hills and valleys, moderately dissected hills and valleys, highly dissected hills and valleys, highly dissected plateau, alluvial plain, flood plain, anthropogenic terrain (dam and reservoir), and water bodies (Fig. 5). The massive pediment–pediplain multifaceted is found in the northwest, central, and southeastern part of the basin and covers an extensive part of the study area of which 75.82% consists of gneiss and lateritic formation. Lower part of the basin dominated by alluvial plain, flood plain, and water bodies covers 6.63%, 4.36%, and 2.01% of the study area, respectively. Flood plain deposits and alluvial plains both contain abundant groundwater because of the high recharge rate and peak flow of river water during the monsoon season. The anthropogenic terrain (dam and reservoir) found in the central part and low dissected hills and valleys, moderately dissected hills and valleys, highly dissected hills and valleys, and highly dissected plateau is found in scattered position in central, northwest, and east central part of the study area.
Slope
The steepness of the ground surface is expressed by slope, which is a major terrain attribute. The grade of the slope is an essential terrain feature in determining the groundwater vulnerability. It has a direct impact on the penetration of surface water. A lower value of the slope angle resembles the flatter terrain, whereas the higher slope values indicate the steeper terrain. Because water flows fast downward on steep slopes, precipitation does not have enough time to assimilate; steep slopes are connected with limited recharge potential. Groundwater recharging can take longer in locations with gentle slopes. As a result, groundwater recharge is more likely in the gentle slope-dominated region than on steep slopes. A DEM was used to create the slope map for this research. The extended slope data were reclassified into five classes, namely flat (0.00°-2.22°), gentle (2.23°-5.04°), medium (5.05°-8.87°), steep (8.88°-16.52°), and very steep slopes (> 16.53°) (Fig. 6). According to this classification system, the majority of the research area (39.20 percent) has a level terrain, whereas 0.82 percent to 5.09 percent of the area has a steep to very steep slope.
Elevation
Elevation is important in controlling the stream gradient, which determines the groundwater potentiality in a drainage basin from the highest to the lowest altitude per unit area (Patra et al. 2018; Das and Pal, 2020). Elevation range in the present study area has been classified into five classes, i.e., above 373–659 m (2.14%), 240–372 m (21.19%), 175–239 m (25.16%), 98–174 m (19.63%), and 14–97 m (31.86%) (Fig. 7). The basin’s elevation varies between 97 and 659 m. Low groundwater concentrations range from 659 to 239 m above mean sea level (msl) in the upper basin, owing to high altitude and limited infiltration capacity; however, maximum concentrations range from 97 to 14 m (msl) in the lower basin, owing to massive water logging and a low gradient ratio (CGWB 2014). Therefore, various weightage values have been assigned for different elevation.
Land use/Land cover
The magnitude of groundwater demand and consumption is determined by land use and land cover (Jhariya et al. 2016). It also offers information on groundwater recharge (Singh et al. 2011). The study area’s land use and land cover map were created using Landsat-8 satellite photographs obtained from USGS Earth Explorer and classified using ArcGIS 10 software’s supervised classification algorithm. Land use and land covers have a great impact on hydrogeological and geo-hydroclimatic process in the water cycle, viz. runoff, infiltration process, and evapotranspiration. Groundwater recharge is influenced by these mechanisms. Water bodies, bare land/wetland, agricultural land, dense forest, shallow forest, and settlement are the six kinds of land use/land cover in the Kangsabati River basin (Fig. 8). The maximum area is dominated by dense forest and agricultural land which is above 50% of the study area. Bare land/wetland, settlement, shallow forest and water bodies cover the rest. Water bodies have a heavier load since they are an excellent source of groundwater replenishment. Agricultural fields with dense vegetation also play a part in recharging the groundwater, and as a result, they have a high weight. The rates of infiltration are proportional to the density of the vegetation, as higher infiltration rates and less runoff are encouraged. As a result, the vegetation-covered surface receives significant weighting. However, because they provide a low infiltration rate, bare ground and built-up areas have been given a low weighting.
Drainage density
The course of a stream per unit area in a basin region is referred to as drainage density (Horton, 1932; Strahler, 1952). The nature and structure of rocks, soil qualities, and slope gradient, among other factors, all influence drainage density (Manap et al. 2013). The density of drainage is measured by how near the channels are spaced. The opposite functional feature of permeability is the drainage density of a river basin. Increased runoff results from higher drainage density, which reduces water infiltration into the subsurface and vice versa (Bera et al. 2019).
where \(\sum {Di}\) is the total stream length in the grid (km) and \(A\) is the grid area (km2).
The drainage density of the Kangsabati River basin has been classified into five classes, i.e., very low (0.04–0.68 km/km2), low (0.69–1.32 km/km2), moderately low (1.33–1.97 km/km2), high (1.98–2.61 km/km2), and very high (2.62–3.25 km/km2), covering an area of 914.63 km2, 2544.12 km2, 2107.35 km2, 820.61 km2, and 101.18 km2, respectively (Fig. 9). Low and very low drainage density zones make up roughly 53.13 percent of the total area, and they have higher weightage values than high drainage density zones.
Rainfall
In the research area, rainfall is the principal source of groundwater recharge, and it plays an important role in the hydrological cycle. Rainfall nourishes the region’s rivers while also regulating groundwater levels. Rainfall is responsible directly for the recharge potential of groundwater as it helps in groundwater storage through infiltration process. The pace of infiltration is affected by the amount of rain and how long it lasts. Short-duration, high-intensity rain causes more surface runoff and less infiltration, whereas long-duration, low-intensity rain causes a higher infiltration rate than runoff (Adhikary et al. 2018; Bera et al. 2020; Ibrahim-Bathis and Ahmed 2016). Rainfall data from the years 2010 to 2019 were used in this investigation. The annual rainfall is between 1332.07 and 1599.92 mm. On ArcGIS, the geographical distribution of rainfall was created using the kriging interpolation method. The rainfall map was reclassified into five classes such as very low (1332.07–1378.47 mm), low (1378.48–1421.70 mm), moderate (1421.71–1477.59 mm), high (1477.60–1534.54 mm), and very high (1534.55–1599.92 mm) (Fig. 10).
Soil
Fluvisols are relatively young soils with little horizon stratification; they often exhibit AC profiles and are brown (aerated soils) or grey (waterlogged soils) in color. They can range in texture from coarse sand in levee soils to thick clays in basin locations. Luvisols have a (greyish) brown to brown or red argic subterranean horizon over a brown to dark brown surface horizon. Leptosols are relatively shallow soils with little expansion that occur on hard rock or calcareous materials. Deeper soils on gravelly and stony parent materials that lack fine earth are also included. There are soils having a lot of shrinking/swelling clay minerals in them. Clay minerals compress and swell, causing self-mixing. Organic matter content is varied, and the color is dark (1–6 percent). Archisols have porous surface soils that are protected by a protective forest canopy. The precious A-horizon degrades and slakes to form a hard surface crust when the forest is destroyed. The crust prevents enough penetration. Cambisols are distinguished by the paucity of illuviated clay, organic content, and aluminum and/or iron compounds, as well as minor or moderate weathering of the parent material (Fig. 11).
Curvature
Curvature values are used to portray the morphology of regional geometry. A convex surface has a positive curvature, while a concave surface has a negative curvature. The value zero denotes a flat surface. Because soil thickness is relatively higher in areas with concave slopes, soils in these areas continue to gather more water than soils in areas with convex slopes. Convex slopes, on the other hand, shed more surface runoff than concave slopes. The study area was divided into three categories based on slope curvature. These are concave (-10.14 to -0.63), flat (-0.62 to 0.27), and convex (0.28 to 10.59) (Fig. 12). The study area is mostly flat, with concave and convex profiles covering 11.84 percent and 25.63 percent of the study area, respectively.
Topographic wetness index
The topographic wetness index (TWI) was first developed by Beven and Kirkby (1979) as part of a runoff model. In a regional topography, TWI represents the overall allocation of wetness scenarios. In simple terms, it represents the slope-to-specific catchment area ratio. This index determines the water accumulation propensity as well as the gravitational attraction’s proclivity to relocate water downslope. TWI values of Kangsabati River basin vary from 3.22 to 20.74. Within the Kangsabati River basin, TWI was classified into five classes, i.e., extensively high (11.55–20.74), high (9.00–11.54), moderate (7.42–8.99), low (6.25–7.41), and very low (3.22–6.24) (Fig. 13). The normalized TWI divides recharge zones into two categories: discharge zones and likely recharge zones. TWI values are high in areas with a lot of flow accretion and linear slopes. Rainfall runoff characterizes recharge zones, which allow water to permeate into the soil and so reach the underlying water table, whereas discharge zones are defined by rainwater runoff.
TWI is represented by the following formula:
where \(As\) is the specific catchment area and \(\tan \beta\) is the slope angle of the specific grid.
Groundwater Potential Zone
The Kangsabati River basin’s groundwater potential zones (GPZ) were created by overlaying weighted factors such as geomorphology, geology, land use, drainage, elevation, slope, lineament, soil, rainfall, curvature, and topographic wetness index in the spatial analyst tool of ArcGIS using AHP and GIS techniques. Overlay analysis is a multi-criteria assessment that involves awarding a rank to individual factors and then allocating a weightage of sub-factors to that specific feature based on its impact on the criterion (Barik et al. 2016). The Kangsabati River basin’s predicted GPZ was divided into five zones: very low (28.93 percent of the area), low (30.56 percent of the area), moderate (19.75 percent of the area), high (14.11 percent of the area), and very high (14.11 percent of the area) (6.11 percent of the area) (Fig. 14, Table 7). Because of the accessibility of loamy textured well-drained soil, high intensity of rainfall, existence of lineament, gentle slope, and massive agricultural land with excellent infiltration capability, the findings demonstrate that the fantastic GPZ was focused in the central and southeastern parts of the basin, especially in Godapiasal, Raipur, Medinipur, and Khemasuli regions. Rainfall is heaviest in the basin’s southeastern section. The northwestern half of the research area (Kotshila, Jhalda, Purulia, Aharrah, Kantadihi, and Barabazar regions) has very poor or low prospective owing to the combination of poorly drained soil and fine-grained basaltic hard rock beneath, which makes groundwater recharge difficult. Geomorphology, slope, land cover, and soil type are the key characteristics that may have an impact on groundwater potential in this area. In the current environment of high demand for groundwater, identifying potential groundwater zones is critical since the perspective of any resource allows for reconsideration and further improvement in that resource. As a result, the delineation of a prospective groundwater zone in the Kangsabati River basin gives regional planners a notion of how to best manage the available water and contribute to long-term development.
Validation of GWPZ using water table data
The receiver operating characteristic (ROC) curve has been used to depict the amount of precision of groundwater potential zones (Mohammady et al. 2012; Pradhan, 2013). The data from existing boreholes are referenced to the groundwater potential zone map in this graph. The area under the curve (AUC) of the ROC curve (Fig. 15) is 0.745, which corresponds to 74.5 percent. As a result of this model’s accuracy of greater than 70%, the AHP approach can be acknowledged as a straightforward tool for generating groundwater potential zones.
Groundwater fluctuation map is created by researching the region’s seasonal groundwater fluctuation (CGWB 2019). Low groundwater potentiality is found in areas where water levels fluctuate a lot, and high groundwater potentiality is found in areas where water levels fluctuate less. In this study, 35 wells were examined for the purpose of determining the depth of water level data for the years 2019 and 2020. With the use of IDW interpolation, pre-monsoon and post-monsoon maps were constructed based on the obtained data. The maps show how the water level in the Kangsabati River basin varies over time. The northwestern part of the basin has a deeper depth than the other regions, according to the pre-monsoon map. In the post-monsoon season, the center and southeast regions of the basin have shallower depths than the north and northwestern parts. From the raster calculator method, groundwater fluctuation map (Fig. 16) has been created. This map indicated that in the high GWPZ, the groundwater fluctuation is low and vice versa. Based on this finding, a scatter plot has been made to understand the relation between GWPZ and groundwater table fluctuation (Fig. 17). Groundwater potential zone has a negative relationship with groundwater fluctuation, according to the scatter graphs. As a result, the groundwater potential map and the groundwater volatility map are extremely accurate.
Conclusion
The AHP approach, in combination with remote sensing and GIS, was successfully used to designate groundwater potential zones in the Kangsabati River basin in this study. According to the findings, approximately 14.62 percent and 6.11 percent of the region are in high to extremely high potential zones. As a result, the study of groundwater potential zones encompasses the interaction between groundwater occurrence and various physical characteristics such as geology, geomorphology, rainfall, drainage, lineament, curvature, TWI, and so on. The applicability of the AHP method for identifying groundwater potential zones using ROC curve is also discussed in the study. As a result, it is a systematic investigation in which a quantitative method was used to manage the groundwater supply. In an era of resource depletion, this study is extremely useful since the final map will be useful to authorities involved in land use planning and water resource management. The results were confirmed using pre-monsoon and post-monsoon groundwater depths to ensure that the applied approach was appropriate for the study, indicating that it was.
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Acknowledgements
The authors show their kind acknowledgment to the Dept. of Geography and Microbiology, Raja N. L. Khan Women’s College (Autonomous), Medinipur, West Bengal, India, for their laboratory facilities and kind encouragement.
Funding
This research was supported by the Department of Geography, Raja N. L. Khan Women’s College (Autonomous), affiliated to Vidyasagar University, Midnapore, West Bengal, India. The author (P. K. Shit) gratefully acknowledges West Bengal DSTBT for financial support through R&D Research Project Memo no. 104(Sanc.)/ST/P/S&T/ 10G-5/2018.
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PK Shit conceptualized and planned the study and reviewed and edited the manuscript. AG conducted the survey, analyzed the data, and interpreted the results. GSB reviewed and edited the manuscript. PPA reviewed and edited the manuscript. BB supervised the study and reviewed and edited the manuscript. All authors have read and approved the final manuscript.
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Ghosh, A., Adhikary, P.P., Bera, B. et al. Assessment of groundwater potential zone using MCDA and AHP techniques: case study from a tropical river basin of India. Appl Water Sci 12, 37 (2022). https://doi.org/10.1007/s13201-021-01548-5
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DOI: https://doi.org/10.1007/s13201-021-01548-5