Abstract
Groundwater potential of some parts of Cross River State, Nigeria, was assessed involving vertical electrical sounding (VES) and high-resolution aeromagnetic methods (HRAM). The VES and HRAM dataset were used to delineate the hydro-lithostratigraphic units and map the spatial distributions of geologic structures, respectively. The electro-stratigraphic sections revealed the various hydro-lithostratigraphic units composed of fractured/weathered crystalline basement, sandstones, siltstones, sandy shales, and highly baked and fractured shales occurring at different depths. Generally, the unsaturated top layer is composed of shales, marl, clay, silt, gravel and lateritic materials with resistivity ranging from ~ 3.0 to ~ 550 Ω m. This layer is underlain by various aquifer units like sandstones, siltstones, fractured shales and limestone/marl, and fractured/weathered basement occurring at different depths (~ 30 to ≤ 100 m) as revealed by the electro-stratigraphic sections obtained in the study area. In the Calabar Flank (CF), Oban Massif (OM) and Ikom-Mamfe Embayment (IME), the apparent resistivity for these hydro-lithostratigraphic units varied between ~ 8.50 and ~ 59.50 Ω m, ~ 120.2 and ~ 1562.6 Ω m and ~ 30.8 and ~ 277.2 Ω m, respectively. The enhanced total magnetic intensity maps and source parameter imaging result showed that the OM and IME are characterized by high concentration of short-wavelength anomalies, while the CF is dominated by relatively undisturbed thick sedimentation (~ 6217 m). HRAM results show that such areas are predominated by geologic structures like faults, fractures, fissure, dyke swamps, etc. caused by tectonics. Such geologic structures create secondary porosity and enhance permeability. From all the results obtained, OM and IME represent areas with moderate groundwater potential. The CF dominated by argillites with no significant tectonic activity is observed to have low groundwater potential.
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Introduction
All human activities are sustained by water. The ability of man to provide sufficient and potable water has remained a major challenge all over the world. The available surface water resources in Cross River State (CRS) which are mostly polluted are obviously inadequate to meet the water requirements for various purposes (Akpabio et al. 2008). This is due to the growing population, rapid urbanization, and agriculture- and industry-related activities. In order to provide sufficient potable water, both the Federal and Cross River State Government Agencies in partnership with numerous local and international donor organizations like Cross River Basin and Rural Development Authority (CRBRDA), Cross River State Water Board Limited (CRSWBL), Cross River Rural Water Supply and Sanitation Agency (CR-RUWATSSA), Cross River Rural Development Agency (RUDA), Cross River State Community and Social Development Agency (CRSCSDA), Micro Project Programme in Nine Niger Delta States (MPP9), Niger Delta Development Commission (NDDC), European Union (EU), United Nations Children Emergency Fund, Concern Universal, Millennium Development Goals (MDGs), etc. have been involved in several groundwater development programmes in CRS. Their activities have increased public boreholes sited at public schools, primary health centres, village squares, etc. Despite the huge financial investments in the water sector, some of these boreholes are either of low groundwater yield or completely failed projects.
According to Okereke et al. (1998), successful boreholes drilled in Cross River State are less than 40% since a lot are either failed or of marginal yield. The low success rate is attributed to unscientific approach in groundwater exploration and random siting of boreholes, uneven distribution of groundwater resources because of complicated geologic history of the terrain (Akpan et al. 2013), and wrong analyses and interpretations of geophysical data. In order to generate information that could serve as valuable guide in groundwater exploration, and extensively assess its potential in some parts of CRS, electrical resistivity and high-resolution aeromagnetic methods were used. This study is aimed at delineating the hydro-lithostratigraphic units and mapping the spatial distribution of geologic structures and their influence on groundwater yield within the investigated area. However, several geophysical methods like electrical resistivity, seismic, gravity and ground penetrating radar methods can be used to explore for groundwater resources (Kearey et al. 2002). The spatial distribution and depth to the various hydro-lithostratigraphic units can be studied using electrical resistivity technique involving vertical electrical sounding and Schlumberger electrode array (Ebong et al. 2016; Akpan et al. 2013, 2014). This method is fast, economical, non-invasive, environmental-friendly (Ebong et al. 2016), and the equipment are readily available. However, such data are sometimes associated with errors arising from inherent ambiguities in the transformation of electrical resistivity data to their corresponding geologic models (Ebong et al. 2014). The ambiguities are commonly solved by matching geologic information with geophysical data (Ebong et al. 2016). Aside the aforementioned setbacks associated with the electrical resistivity technique, it cannot be used to probe depths exceeding 1000 m (Kearey, et al. 2002). To address this problem, and determine the effects of tectonic on groundwater yield, magnetic method involving image analyses and magnetic enhancement procedures were used to map the geologic location of the occurrence of faults, fractures, fissures and dyke swamps (Ekwok et al. 2020). However, the magnetic data inverse difficulty is often ill-posed, thereby making the solution unstable and non-unique (Essa and Elhussein 2017). A reliable solution of an ill-posed problem can be realized by applying certain advanced methods or has a priori geologic knowledge (Ekwok et al. 2020; Essa and Elhussein 2018).
Electrical resistivity method is well established (Araffa and Pek 2014) and widely used for geologic, geotechnical and archaeological studies (Kelly 1977). Also, the technique has been effectively used in resolving a diverse range of hydrological, hydro-geophysical, engineering and environmental challenges (Ebong et al. 2016), including aquifer mapping and geo-hydraulic parameter estimation (Ebong et al. 2014; Kudamnya and Osumeje 2015), characterization of water-bearing zone, evaluation of infiltration rate of the vadose zone and groundwater contamination investigations (Akpan et al. 2013; Mhamdi et al. 2015). Over the years, geo-electrical resistivity method employing vertical electrical sounding (VES) procedure and Schlumberger electrode array has proved to be very suitable for groundwater exploration. Several researchers like Bose et al. (1973), Urish and Frohlich (1990), Edet and Okereke (2002), Wattanasen and Elming (2008) and many others have used this technique to explore for groundwater.
Magnetic method is the most versatile of all geophysical prospecting techniques, and their maps can show multitude of local anomalies (Telford et al. 1990). Presently, magnetic method is used to map faults, fractures, basement topography and character. Also, it can be used to estimate sediment thicknesses in oil/gas exploration (Gunn 1998) and identify different kinds of ore bodies in mineral prospecting (Ekwok et al. 2019; Kearey et al. 2002). Magnetic surveying also finds application in detecting buried fire pits, metal objects and foundations in archaeological studies (Rivas 2009), delineating fault and fracture zones in engineering investigations, studying the magnetic field of the Earth and its generator. Additionally, it is employed in geo-hazards assessment, geothermal exploration and environmental studies. Recently, it has become possible to detect weak magnetic anomalies originating from sedimentary rocks such as faulting of sandstones (Ekwok et al. 2020), appraisal of potential fracture and fault zones, and to assess groundwater potential in hard rock areas (Ekwok et al. 2019). Regions characterized by high concentration of short-wavelength magnetic anomalies are commonly dominated by geologic structures like faults, fractures, fissures, dyke swamps, etc. (Gunn 1998). Such geologic structures are typically caused by extensive tectonic activities and are assumed to have enhanced porosity and permeability (Ekwok et al. 2020). In the Lower Benue Trough and adjoining areas, such features are widespread (Ekwok et al. 2019), and they control the localization, intensity, the direction and character of groundwater movement (Ekwok et al. 2020). To determine these geologic structures, standard data enhancement procedures like first vertical, second vertical and horizontal derivatives, downward continuation and application of gridding routines were performed. In order to assess the spatial distribution of magnetic sources and their depths, depth determination technique like the source parameter imaging (SPI) was used. All the operations were performed using codes available in Oasis Montaj version 7.0.1 (OL) (2008) from Geosoft®.
Location, climate and hydro-geological conditions of the study area
Geographically, the area is situated between latitudes 5° 00ʹ and 6° 00ʹ N of the Equator and between longitudes 8° 00ʹ and 9° 00ʹ E of the Greenwich Meridian. This area falls within the hot, wet tropical climatic zone extending from the southern lowlands in the coastal areas to the central hinterland parts of Cross River State. It enjoys a tropical humid climatic condition, which is dominated by the West African Monsoon system. The region lies within the geographical zone that witnesses two distinct seasons: the wet and dry seasons (Duze and Ojo 1993). However, the climatic condition of the region is controlled by the movement of intertropical convergence zone which leads to contrasting dry and wet periods (Balogun 2000). The rainy season generally begins in the month of March and terminates in October witnesses highest rainfall between the months of June and September, with dry spell of 2–3-week duration in late July to August (Monanu 1975). The dry period which runs from November to February is characterized dry north-easterly trade wind from the Sahara Desert (commonly called Harmattan) that conveys fair and dusty weather to the area. Generally, in the wet season temperatures are lower than in the dry season and differ slightly from the coast to inland areas. Temperature fluctuations usually range between 21.9 and 31.7 °C (Edet and Okereke 2014).
The rain that falls in the rainy season is a major source of recharge for both the surface and groundwater resources in the study area. Aquifer can exist in an unconfined or confined state. The shallow aquifers (< 50 m) in the area are fractured shale and limestone, sandstone and siltstone, fractured and weathered basement rock. The deformations that have enhanced the porosity of these rocks are caused by minor tectonism. Hence, the major hydro-geological units include the fractured and weathered crystalline basement complex, sandstone, siltstone, and fractured shale and limestone. These hydro-geological units within the study area occur in a localized pattern (Edet and Okereke 2014). The northern parts of the study area is directly drained by the Cross River and its tributaries characterized by V-shaped valley. The Kwa, Calabar and Cross Rivers and their tributaries drain the southern areas directly.
Geologic settings
Geologically, the study area is composed of some parts of CF, IME and OM (Fig. 1). The Cretaceous CF and IME are flanking sub-basins of the Benue Trough. The Benue Trough originated during the rifting of Afro-Brazilian plate in early Cretaceous time (Benkhelil 1987). The trough is described as a major structural depression or a failed arm of an RRR triple junction linking the South Atlantic, the Gulf of Guinea and the Benue Trough Benkhelil (1987). Within the theory of plate tectonics, Burke et al. (1971) proposed an active oceanic spreading along the Benue Trough and development of about 150–200-km-wide oceanic crust underneath the Lower Benue, accompanied by a subduction motion along a Benioff zone which caused more than 1300 m of basaltic, andesitic and pyroclastic rocks displayed a modified RRR triple junction model in which the Benue Trough formed an arm with a restricted spreading amounting to no more than a few kilometres of crustal stretching. Burke and Dewey (1974) advocated an aulacogen model for the Benue Trough. Accompanying marine incursion into the trough resulted to the buildup of Cretaceous sedimentary series ranging in age from Albian to Maestrichtian (Burke and Dewey 1974). These sediments sit on the Precambrian to Lower Paleozoic basement rocks composed of mainly schists, gneisses and migmatites.
The CF area contains about four thousand metres (4000 m) of Cretaceous sediments in outcrop section (Ramanathan and Fayose 1990) and is bordered in the south by the Tertiary Niger Delta Hinge line, in the north by the basement rocks of Oban Massif, in the east by the Cameroon Volcanic Line and in the West by Ikpe Platform. Two sets of sediments comprising lower and upper Cretaceous are predominant in the CF.
The former, technically called Awi Formation, is dominated by fluvio-deltaic, cross-bedded, Aptian sandstones (Adeleye and Fayose 1978). The latter, Odukpani Group, comprises of Mid–Albian to Early Cenomanian Mfamosing Limestone Formation and a thick succession of grey–black, carbonaceous Cenomanian Ekenkpong Shale (Petters et al. 1995). Overlying this is a thick Coniacian, calcareous New Netim Marl. It is unconformably overlain by the carbonaceous dark Nkporo Shale (Reyment 1965).
The Precambrian OM in south-eastern Nigeria is bordered by younger sedimentary rocks of mainly Cretaceous age. It shares its boundary with IME in the north, the Cameroon Volcanic Line in the east, the Benue Trough in the west and the CF in the south. The major rock units in the area are phyllites, schists, gneisses, migmatites and amphibolites. Phillites and schists regions are widespread in OM, particularly in the western part (Oden et al. 2012). Most of the prominent fractures in the OM are oriented in a predominantly NNW–SSE direction (Oden et al. 2012). However, there are other minor fractures that trend in a NNE–SSW, E–W and NW–SE directions (Oden 2012). These rocks have been extensively intruded by volcanics, granitic and charnockitic rocks of Pan-African age (Okereke et al. 1998).
The IME sediments consist mostly of conglomerate, shale, sandstone, siltstone, mudstone, limestone, clay, marl and loose sand that have been locally baked, fractured, domed and deformed (Benkhelil et al. 1975; Etuk et al. 2008; Akpan et al. 2013). It is an annex of the Benue Trough of Nigeria (Nguimbous-Kouoh et al. 2012) and forms a major tectono-stratigraphic structure on the African continent (Olivier et al. 2015). It has a width and length of about 60 and 130 km, respectively (Petters 1989); the basin is oriented in nearly East–West direction (Kanouo et al. 2012). It is adjoined in the north by the Precambrian Obudu Plateau, in the south by the Precambrian Oban Massif and in the western part by the Anambra Basin where it proceeds as a south-east extension of the Benue Trough. It gets thinner and ends underneath the Cameroon Volcanic Line (CVL) in the eastern and north-eastern regions. The Ikom-Mamfe Embayment straddles the borders of Nigeria (around Etung and Ikom) and some areas of central Cross River State, Nigeria, and Cameroon (Manyu District of the Southwest Province of Cameroun) where it is known as Ikom-Mamfe Embayment (Petters 1989). The sedimentary successions that constitute the IME consist of a broad range of complex lithofacies and lithologies (Ebong et al. 2016). Abolo (2008) cited that the sediments belong to a particular formation which is called the Mamfe Formation. According to Olivier et al. (2015), the sedimentary series of Ikom-Mamfe basin is underlain by the highly faulted schists, and migmatitic and granitic gneiss rocks of the Pan-African Mobile Belt (550 ± 100 Ma) that constitute the basement in this region. The sedimentary and basement rocks in this area are invaded by Tertiary-Recent volcanic rocks like syenites, diorites, trachytes and basalts, perhaps as a result of the continuing low-grade tectonic activity originating from the adjoining Cameroun Volcanic Line (Ajonina et al. 2002).
Methods of study
Electrical resistivity data acquisition and analyses
Geo-electrical resistivity technique is one of the geophysical methods employed in this study. The method uses two pairs of electrodes—a pair of potential and current electrodes, connected using wires to a resistivity meter. The geo-electric measurements were taken using an Integrated Geo Instruments and Services (IGIS) resistivity measuring meter (model SSR-MP-ATS).
Apart from the protected rainforest reserve of the Akamkpa National Park, fifty (50) soundings point were carried out within the study area (Fig. 2). Some soundings were sited near borehole locations that aid correlation of resistivity data using lithologs from boreholes. Measurements were taken with current electrode separation (AB) ranged between 600 and 1600 m, while potential electrode separation (MN) is in the range of 0.5 and 40 m. The values were selected to optimally map both shallow (< 50 m) and deep hydro-geological units (~ 260 m), assuming that the depth of penetration is over one-sixth of the highest current electrode separation. In order to maintain a measurable potential and ensure quality control in the course of data acquisition, crossover point values are chosen to be twice their previous values, so that measured resistance values can visually be transformed and matched with preceding values at the same current electrode location. Global position system of model GPS Map 76C was used to acquire the locations of resistivity soundings points.
Measured resistivity data were plotted manually in the field on a log–log graph by plotting apparent resistivity (ρa) on the ordinate against half-current electrode spacing (AB/2) on the abscissa axes, respectively. The procedure was repeated for all resistivity stations to evaluate the integrity of the data obtained. Curve matching and smoothening procedures were also employed where necessary, and qualitative analyses were done according to Zohdy (1989). Based on this initial interpretation, a preliminary approximation of layer parameters was obtained.
The estimates were then employed in the modelling process involving RESIST software developed by Velpen (1988). The software used matched the measured data with the synthetic models and revealed their disparities by the root-mean-square (RMS) method. High RMS errors were predominant in noisy datasets, which were linked to current/potential electrodes planted at different lithologic units or poor electrode–ground contacts. These noisy data were either filtered manually or removed by applying a user-defined filtering standards associated with the software. Iterations were done to lessen the RMS errors. The error values for most of the models did not exceed 5%. Above this value, the preliminary input parameters were altered, and the iteration procedure started all over. An inversion procedure after a series of iterations developed models that best fit the curves in a least square sense (Inman 1975).
Airborne magnetic data acquisition and analyses
The data were acquired using Flux-Adjusting Surface Data Assimilation System (FASDAS) with a flight line spacing of 0.1 km, tie line spacing of 0.5 km and terrain clearance of between 80 and 100 m along 826,000 lines. The flight line orientation was basically north-west–south-east, while tie lines, which were designed to traverse the main geologic strike direction, were oriented primarily in a north-east–south-west. The measured data were of very high resolution when compared to the 1970 airborne geophysical datasets and were submitted in gridded and digitized format to Nigerian Geological Survey Agency (NGSA). These recent dataset were observed to be appropriate for hydrocarbon and mineral explorations as well as geologic mapping. The total magnetic field, inclination and declination mean values gotten in the study area are 32,884.2 nT, − 15.8° and − 2.6°, respectively. The regional magnetic field in the measured magnetic data was eliminated by applying the tenth (10th) generation of International Geomagnetic Reference Field Program (IGRF—version 4.0) by Fugro Airborne Surveys, Canada. The major advantage of the IGRF is the consistency it provides in magnetic survey practice right from when the IGRF is generously made available and commonly accepted (Reeves et al. 1997). The magnetic data employed in this study were corrected and processed to TMI gridded map. The measured data (Fig. 3) were subjected to the necessary data reduction processes by Fugro Airborne Surveys, Canada. The HRAM data which include sheet numbers: 314 (Ugep), 315 (Ikom), 323 (Uwet) and 324 (Oban) used for this study were released at subsidized rate by the Nigerian Geological Survey Agency (NGSA), Abuja.
Gridding operation was performed on the data in order to interpolate them from their measurement points to nodes on a regular mesh, thus generating a new and basically different version of the data (Foss 2011). The dataset were gridded applying minimum curvature technique (Briggs 1974). Once a grid is produced, the output was viewed as an image. The images were produced in the Geosoft® software package and exported in the GeoTIF format, including associated files that contain spatial reference information. Gridding of the data enables them to be filtered since filtering requires equally spaced data points. The enhancement operations like first vertical (1VD), second vertical (2VD) derivatives and total horizontal (HGRAD) gradient, downward continuation (DC) and source parameter imaging (SPI) were performed on the magnetic data using Oasis Montaj version 7.0.1 (OL) (2008) from Geosoft®.
The first vertical derivative usually emphasizes high-frequency features, while the second vertical derivative highlights shortest wavelength (highest frequencies) sources. These vertical derivatives enhance near-surface geologic features caused by post-Cretaceous tectonic intrusions. These methods use the principle that anomalies related to deeper sources attenuate more slowly than those related to shallow sources (Grauch and Drenth 2009). The first vertical derivative has come to be a basic requirement in magnetic interpretation projects, but the second vertical derivative has a more resolving power (Milligan and Gunn 1997). The total horizontal derivative process involves a phase transformation in addition to an enhancement of high frequencies. It has the result of producing anomaly peaks approximately over the edges of wide bodies and sharpens these peaks to magnify the delineation of the body edges. Some interpreters use this quality of horizontal derivatives to map body outlines. Downward continuation which is another enhancement tool is a mathematical technique that computes magnetic field at a lower level with reference to the measurement surface. This enhancement sharpens the effects of shallow anomalies (enhances high frequencies) by bringing them closer to the plane of observation. Furthermore, the source parameter imaging technique can be employed to define the various depths to magnetic sources. The SPI process based on Thurston and Smith (1997) method uses the relationship of source depth and local wave number (k) of the analytical signal of the measured field. This can be computed for any location within a grid of data through horizontal and vertical gradients estimated magnetic depth. SPI makes the task of interpreting magnetic data significantly easier (Nwosu 2014).
Results and discussion
Geo-electrical characterization and interpretation
Representative geo-electric curves for the different geologic provinces within the study area are presented in Figs. 4, 5 and 6. At the CF, electrical resistivity values are generally low (< 161.0 Ω m) characterized by K, HK and Q curve types. The OM showed the highest resistivity values ranging from ~ 241.3 to ~ 5541.2 Ω m. The geo-electric interpretation of the models revealed dominantly A, H and KH curve types in the OM. The VES data from IME showed three (K type), four (HK and KH curve types) and five (KHK) geo-electric layers. This area is dominated by relatively low to moderate resistivity values varying from ~ 15.3 to ~ 2501.1 Ω m. The geo-electric parameters are summarized and presented in Table 1.
The subsurface models gotten from the sounding data with lithologs from boreholes serving as a control were applied to generate an electro-stratigraphic sections, which reveal the subsurface stratigraphic distributions for various geologic regions. All the VES points used for the generation of the electro-stratigraphic sections were carefully chosen along a line with borehole lithologs (Fig. 2). Based on the geologic provinces of the study area, three electro-stratigraphic sections were generated for various geologic regions in the study area.
The electro-stratigraphic section obtained at the CF was matched with lithologs acquired at Lubrik Construction borehole site, Mfamosing (Fig. 7). The electro-stratigraphic section reveals the lateral and vertical distributions of the various formations through the entire profile. For all the survey points in the CF, the geo-electric resistivity for the first layer ranges between ~ 3.3 and ~ 160.8 Ω m dominated by shale and clayey/shaly laterite. This top layer is underlain by reasonably thick limestone/marl and shaly limestone. This unit has somewhat lower geo-electric resistivity which ranged from ~ 3.1 to ~ 58.4 Ω m. The limestone–shale intercalations are clearly shown in Fig. 7. The shale deposit under National Independent Power Plant (NIPP) electrical resistivity survey point is perched. Furthermore, the shale layer that appears continuous from the south-eastern end is pinch out towards the north-western point of the profile. The limestone is suspected to be the aquifer horizon. However, the primary porosity in these carbonate rocks seems to reduce widely by the compaction and cementation processes all through the period of post-depositional burial (Halley and Schmoker 1983; Mazzullo and Chilingarian 1992). Most pores in carbonate rocks caused by dissolution and dolomitization are classified as secondary porosity, and these may be marginally interconnected. Consequently, these reasons could be the cause of numerous failed and marginal yield boreholes in the area.
From the electro-stratigraphic cross section (Fig. 8) which traverses parts of the OM in the north–south direction, three distinctive geo-electric layers were detected. The lithologic logs obtained from a borehole located in Ibiae palm plantation served as control in the interpretation of the electro-stratigraphic section. Figure 8 captures the vertical and lateral distributions of the geo-electric parameters of the profile. The first layer resistivities (~ 219.9 to ~ 1161.1 Ω m) and depths that ranged from thin to somewhat thick (5-33 m) were interpreted to be lateritic overburden (clayey, silty, sandy or gravelly materials) of different grain sizes. The second layer, composed of weathered basement rock having geo-electric resistivity values which vary approximately between ~ 193.5 and ~ 689.7 Ω m, is the main water-bearing unit. Edet and Okereke (1996) also reported closely related resistivity range (~ 280 to ~ 740 Ω m) for the OM aquifer. The aquifer horizon which is fairly homogeneous increases progressively from about 15–30 m thick in the north–south direction along the profile. From the interpreted section, the potential depth for boreholes within the OM lies between 50 and 60 m. This potential production depth range is in contrast to Edet and Okereke (1996) recommendation of 30–50 m. The third layer which has resistivity values generally greater than 1000 Ω m, but less than 5400 Ω m, is characterized as non-fractured crystalline basement.
Further, the electro-stratigraphic section and borehole log in the east–west direction (Fig. 9) reveal the lateral and vertical hydro-geological changes in the Nigerian sector of IME. At the basal sections of the basin lies an alternating sequence of highly bioturbated sandstone, silty shale and shale with siltone, ironstone and mudstone intercalations (Ekwueme et al. 1995). The section showed three, four and five geo-electric layers with hydro-lithostratigraphic units occurring at different depths. The top layer (< 5 m) of the profile showed lateritic, silty, clayey, sandy or gravelly materials and characterized by very low to moderate electrical resistivity (~ 10.5 to ~ 2358.4 Ω m).
On the whole, the second layer (about 5–20 m thick) dominated by sandstone, siltone and sandy shale/clay materials has geo-electric resistivity values ranging from ~ 50 to ~ 350 Ω m. At the western end of the profile, this second layer is a hydro-lithostratigraphic unit composed of calcareous Amaseri sandstone ridge of Turonian–Coniacian age which grades into a shaly formation (Ebong et al. 2016; Odigi and Amajor 2009). Geo-electric layer three (< 20 m thick) which appears to be continuous with resistivity (~ 60 to ~ 500 Ω m) typifies calcareous and sandstone and marine shale (Edet and Okereke 2014; Petters 1982). Directly underlying this unit is a relatively lower resistivity layer (30–300 Ω m) composed of sandstone, siltstone and shale that are highly baked and fractured. This geo-electric layer is the major aquifer unit of the IME. Ebong et al. (2016), Akpan et al. (2013) and Petters (1989) described the area as having moderate groundwater yield which is the main source of potable water. Edet and Okereke (2014) classified the hydro-lithostratigraphic units within IME as Amasiri, Ezeaku, Mamfe and Volcanic aquifers, respectively, in the west–east direction.
Interpretation of magnetic enhancement maps
The first vertical derivative (Fig. 10a), second vertical derivative (Fig. 10b), downward continuation (Fig. 10c) and horizontal gradient (Fig. 10d) accentuated shorter wavelengths magnetic anomalies. Such magnetic anomalies indicate the location of geologic features like faults, fractures, fissures, etc. dominated region.
The CF located at the south-western region of the study area is dominated by carbonates and argillaceous sediments which have effectively lowest average susceptibility. In sedimentary rocks, the usual cause of magnetic anomalies includes dykes, folded, faulted or truncated sills and lava flows, massive basic intrusions, metamorphic basement rocks and magnetite ore bodies (Kearey et al. 2002). The enhanced maps show little or no evidence of magnetization in the CF from ferromagnetic materials or post-depositional intrusions. In a continuous depositional environment like the CF, an exponential decrease in primary porosity is expected due to progressive burial and compaction (Hilchie 1978). Additionally, the basal Awi Formation at the CF dominated by Aptian sandstones (Adeleye and Fayose 1978) is overlain by about 4000 m (Ramanathan and Fayose 1990) of Mid–Albian to Maastrichtian Odukpani Group (Petters et al. 1995). Generally, boreholes drilled in this area are generally less than 300 m. The lack of secondary porosity and permeability, caused by post-depositional intrusions and the considerably deep burial of sandstone unit, are the reasons for several failed or marginal yield boreholes observed at CF.
The OM (defined by densely packed red–pink colour) trends in the north-west–south-west direction show high concentration of short-wavelength anomalies. The basement rocks composed of mainly granites, biotite gneisses and some igneous intrusions (Ekwok et al. 2020; Edet and Okereke 1996) are composed of magnetite and are considered to be the cause of the high magnetization witnessed in the area. Mechanical disruptions by tectonic events have caused severe deformation of Precambrian crystalline basement rocks. These activities have created secondary porosity and permeability by fracturing, fissuring and shattering of the crystalline rocks (Edet and Okereke 1996). These geologic structures are believed to enhance the groundwater potential of the OM.
From the enhanced maps (Fig. 10) in the IME, the spatial distribution of the major short-wavelength anomalies (represented by unevenly distributed red–pink colour) agrees relatively well with each other. The maps show a very good clustering of symbols in curved and linear fashion suggesting the probable nature of contacts between rock units and expressing the various geometrics of the causative bodies. These imprints of tectonic-shaped landscape were previously described by Petters (1989). Ekwueme et al. (1995) reported the occurrence of ironstone and other lithologies like sandstone, siltstone, silty shale and shaly siltstone in the IME. Intrusions, ironstones and other near-surface ferruginous materials are the main cause of high-frequency magnetic anomalies observed in the IME. The region is dominated by sequences of Post-Turonian basic to intermediate igneous bodies and Tertiary-Recent basic intrusives (Edet and Okereke 2014). Most of the igneous bodies occur in the form of minor sills and show vertical and horizontal joints (Hossain 1981). Most igneous rock intrusions will have negligible primary porosity, and their thermal effects can be observed several kilometres away from the most proximal intrusions (Duddy et al. 1994). Baking and fracturing generated during thermal cooling shortly after emplacement or subsequently during brittle tectonic deformations can provide some secondary porosity and permeability (Rateau et al. 2013). Intrusions to shallow levels may play an important role in influencing groundwater pathways, particularly in areas where dense, interconnected networks of sills and dykes occur (Rohrman 2012), hence enhancing the groundwater potential of the area. The existence of tectonic structures in the IME is expected to enhance the groundwater potential of the region. Additionally, igneous-related hydrothermal fluids are rich in salts like potassium chloride (KCl), sodium chloride (NaCl) and calcium chloride (CaCl2) (Mineral resources of the western US 2017; Oha et al. 2016; Oha 2014; Dill et al. 2010), and heat. These occurrences suggest the IME aquifer may be slightly saline and may have experienced somewhat higher temperatures.
Interpretation of source parameter imaging (SPI)
Source parameter imaging method was developed by Thurston and Smith (1997), and according to Thurston et al. (2000), it is used for evaluating magnetic source depth, geometries and susceptibility contrasts. Average depth generated from the RMA is displayed as an image (Fig. 11). The SPI gridded image shows wide-ranging colours indicating the different magnetic susceptibility contrast that occurs in the study region. Negative signs connote depth measurement from the Earth’s surface downward (Ekwok et al. 2019).
Generally, regions (CF) dominated by blue colour (argillite and carbonate rocks) indicate thick sedimentation (~ 6217 m) nearly devoid of ferromagnetic minerals and intrusions. This depth confirms the deep burial of basal Awi Sandstone Formation with over 4000 m of overlying sediment (Ramanathan and Fayose 1990). The areas (OM and IME) predominated by ferromagnetic and other magnetic materials (lemon green to pink colour) indicate regions with intermediate to thin sediment thicknesses. These areas have witnessed series of low-grade tectonic events (Ekwok et al. 2019). Edet and Okereke (1996) reported that the OM has been intruded by igneous rocks such as dolerites, granodiorites, charnokites, monzonites and pegmatites. Additionally, rocks in the IME are intruded by volcanic rocks like syenites, trachytes, diorites and basalts, probably as a result of the persisting tectonic activity originating from the adjoining Cameroun Volcanic Line (Abolo 2008; Ajonina et al. 2002; Eyong et al. 2003; Okereke and Fairhead 1984). The basement rocks of OM, intrusions and ironstones (Ekwueme et al. 1995) are the main cause of high magnetizations.
Areas with pink colours particularly at the IME show regions with dense, interrelated systems of sills and dykes occurring at depths of less than 36 m. Generally, areas with shallow depths to basement surface are dominated by geologic structures like faults and fractures. The presence of these structures has the capability to enhance the groundwater potential of the area.
Conclusions
Electrical resistivity and high-resolution aeromagnetic data were analysed to offer fresh insight in the hydro-geological framework of some part of CRS. The depth to hydro-lithostratigraphic units and the spatial distribution of geologic structures like faults, fractures, fissures, etc. (caused by tectonic events) were mapped using electrical resistivity and HRAM data, respectively. The electro-stratigraphic sections showed that the different aquifer layers composed of fractured/weathered crystalline basement, sandstones, siltstones, sandy shales, and highly baked and fractured shales exist at different depths (~ 30 to ≤ 100 m). Top layer with electrical resistivity of ~ 3.0 to ~ 550 Ω m is dominated by shales, marl, clay, silt, gravel and lateritic materials. The electrical resistivity of the various hydro-lithostratigraphic units varied between ~ 8.50 and ~ 59.50 Ω m, ~ 120.2 and ~ 1562.6 Ω m and ~ 30.8 and ~ 277.2 Ω m in the CF, OM and IME, respectively. The enhanced HRAM data showed high concentration of short-wavelength anomalies in the OM and IME regions, indicating the existence of geologic features that could improve porosity and permeability of subsurface rocks. Also, the HRAM results showed that the CF is dominated by long wavelength anomalies with no significant post-depositional tectonic signature. These characteristics make the argillaceous CF to be dominated by primary porosity and permeability. The SPI result likewise revealed the spatial distribution of intrusions and depth to basement rocks. The OM and IME have thin to moderate sediment thicknesses, while the CF is predominated by thick sedimentation (~ 6217 m). On the whole, the combined geophysical results revealed that the OM and IME have reasonable prospects, and they could have moderate groundwater yield, while the CF will possibly be of marginal yield.
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Ekwok, S.E., Akpan, A.E., Kudamnya, E.A. et al. Assessment of groundwater potential using geophysical data: a case study in parts of Cross River State, south-eastern Nigeria. Appl Water Sci 10, 144 (2020). https://doi.org/10.1007/s13201-020-01224-0
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DOI: https://doi.org/10.1007/s13201-020-01224-0