Thesis Abstract

Abstract
Groundwater investigation is a crucial aspect of water resource management and environmental studies. Traditional methods like drilling and sampling can be time-consuming and expensive. In recent years, geophysical methods like single-point resistance (SP) and spontaneous potential (SP) logging have gained popularity due to their cost-effectiveness and non-invasive nature. This research focuses on the use of single-point resistance and SP logging in groundwater investigation. The SP method measures the natural potential difference between an electrode in the ground and a reference electrode on the surface. It can detect changes in subsurface lithology and water content, making it useful for delineating aquifer boundaries and identifying potential water-bearing zones. Single-point resistance logging involves measuring the resistance between a pair of electrodes at different depths in a borehole. Variations in resistance can indicate changes in lithology, moisture content, or the presence of fractures or other geological features. By analyzing these data, geologists can infer the hydrogeological properties of the subsurface and locate potential groundwater resources. This study presents a case study where single-point resistance and SP logging were used in conjunction to investigate groundwater resources in a coastal region. The results show a clear correlation between low resistivity zones identified by the SP method and potential aquifer zones identified by the single-point resistance logs. This highlights the effectiveness of combining these two geophysical techniques for groundwater exploration. The research demonstrates the utility of single-point resistance and SP logging in groundwater investigations, particularly in areas where traditional methods may be impractical. These methods provide valuable information about subsurface geology and hydrogeological properties, helping to optimize well siting and design for groundwater extraction projects. Additionally, the non-invasive nature of these techniques reduces environmental impact and minimizes the need for costly and time-consuming drilling operations. In conclusion, the integration of single-point resistance and SP logging offers a cost-effective and efficient solution for groundwater investigation. By providing valuable insights into subsurface hydrogeological conditions, these geophysical techniques play a vital role in sustainable water resource management and environmental conservation efforts.

Thesis Overview

.0 Introduction

Water is one of the abundant and widely used natural resources available to man. Many communities obtain the water they need from rivers, lakes, or reservoirs, sometime using aqueduct or canals to bring water from distant surface sources. Another source of water lies directly beneath most towns. This resource is groundwater, the water that lies beneath the ground surface. The origin of water is traced to the process of the hydrologic cycle. When rain falls on the land surface as precipitation, more than half of the water returns rather rapidly to the atmosphere by evaporation or transportation from plants. The remainder either flows over the land surface as runoff to streams, rivers, and lakes, or soaks into the ground by infiltration to form groundwater. Rivers stream and lakes make up the surface occurrence while those that sink into the ground make up subsurface occurrence called ground water.

Groundwater is the water that lies beneath the ground surface, filling the pore spaces between grains in bodies of sediment and clastic sedimentary rocks and filling cracks crevices in all types of rocks (Plummer et al 1999). The subsurface zone in which all rocks opening are filled with water is saturated zone. The upper surface of the saturated zone is the water table. Groundwater is unfortunately not evenly distributed everywhere. The distribution of ground water depends on large extent upon the types and depth of occurrences (Oseji, 2010). Ground water in its natural state tends to be relatively free of contaminants in most areas. Because it is a widely used source of drinking water, the contamination of groundwater can be a very serious problem (Plummer et al., 1999). Groundwater can be contaminated by pesticides and herbicides (such as diazion, atarzine DEA and 2, 4, D) applied to agricultural crops Can find their way into groundwater when rain or irrigation water leaches the contaminants downward into the soil; Liquid and solid wastes from septic tanlas, sewage plants and animal. Feedlots and slaughterhouse may contain bacteria viruses, and parasite that can contaminate groundwater.

Ground exploitation sometime often result in failed and abortive borehole because of lack of preliminary geophysical investigation required to map and locate prolific zones within the aquifers (Atakpo et al., 2008). In order to avoid such an occurrence and to increase the probability of drilling successful and sustainable borehole, it becomes pertinent and economically wise to carry out prior geophysical investigation. Borehole electrical resistivity and spontaneous potential method is based on the variable resistance in surface materials to the conduction of electrical current depending on materials to the conduction of electrical current depending on variation in fluid content, density and chemical composition of the composition (Paransis, 1986). Recently other electrical geophysical method such as electro-magmatic induction (EM) and ground penetrating radar (GPR) becomes increasingly popular.                

1.1 Location of the Study Area

Otor-Jeremi is the headquarters of Ughelli south local government area of delta state, which came into existence on the 23rd of September, 1997 following the splitting of the defunct ughelli local government area into two, north and south local government areas. She lies between latitude 5o 58139. 011N and 5o 581 3011E and longitude 5o 301 5311N and 6o 011 04 511E. The local government area is made of six major clans namely Ughievwen, Ewu, Olomu, Effurun-otor, Okparabe and Arhavweren which make up the eleven wards of the local government area.

Fig 1: Map of Otor-Jeremi

1.2 Aims and Objective

The aim and objective of this work are.

To determine the lithology of the subsurface using spontaneous potential log.
To determine or identify the aquifer, depths and thickness of the rock using spontaneous potential log.
To determine the quality of water based on total dissolved solids using single point resistance log.
To determine the portability of the water.                                                              
1.3 Scope of the Study

This research work is limited to acquiring of field data using single point resistance log to evaluation of the quality of water based on total dissolved solid (TDS) and the lithology of the subsurface using spontaneous potential log.