INTRODUCTION
The Gongola Basin (arm) of the Upper Benue Trough (Fig. 1)
is a NS trending arm of the 1000 km long Benue Trough. The mechanism of the
formation of the Trough dominated most of the early studies carried out in the
area and, although, still controversial, an unstable RRF (riftrift fault) triple
junction model leading to plate dilation and the opening of the Gulf of Guinea
(Benkhelil, 1989; Fairheada and
Binks, 1991). Benkhelil, 1989 also suggested that
the evolution trough could also be as a result of tension resulting in a rift
or wrench related fault basin, Mesozoic to Cenezoic magmatism has accompanied
the evolution of the tectonic rift as it is scattered all over and throughout
in the trough (Coulon et al., 1996), a magmatic
old rift was also suggested for the Gongola Basin (Shemanget al., 2001).
However, one thing that is not controversial in the trough is its great potentials
for sources of mineral raw materials of economic significance. Deposits of limestone,
bricks and fire clay, construction stone, laterite and coal, all of commercial
importance exist and some are being worked. Significant occurrences of base
metal sulphide (lead with small amounts of copper) cadmium and silver and associated
mineral barites are known to occur in the trough.
Other economic minerals such as coal and diatomite occur in Gombe and Bularafa,
limestone around Ashaka, lowgrade base metals, as well as large potential for
glass sands and mineral (juvenile water) in the trough. Recently, the petroleum
potential of the trough has been of great interest to geologists and geophysicists.
Geological and geophysical studies carried out in the Upper Benue Trough have
shown the area to have all the qualities possessed by the oil producing area
of the trough namely Lower Benue Trough and Middle Benue Trough. The Nigerian
government through the Nigerian National Petroleum Cooperation (NNPC) and many
oil companies have invested heavily in the NE of the trough prospecting for
oil which remains elusive up to today. However, efforts are still on and more
money is still being sunk into the area with the hope of finding oil in the
near future. This being the case, there is need for more geophysical and geological
studies to be carried out in the area to add to the existing data. The research
presented in this study is part of this effort and has the following objectives:
• 
To determine depths to magnetic sources within the study area
using spectral analysis 
• 
To modeled a prominent linear aeromagnetic anomaly in the
area and its source 
• 
To determine the basement topography 
• 
To infer the possible origin of the Basin from all the above 
Spectral analysis of the aeromagnetic field provides a valuable tool for the
determination of depths to magnetic sources. In addition, 2½ dimensional
computer modeling programme can give a composite model of the surface topography
of the basement below the basin and the structure as well as the depth of any
intrusions into the basement. Like most of the published procedures of depth
determination for magnetic sources, the procedure of spectral analysis used
here is based on the method developed by Spector and Grant
(1970). On the other hand, the 2½D programme makes use of algorithms
described by Won and Bevis (1987). The 2½D calculations
are based on Rasmussen and Pedersen (1979).
MATERIALS AND METHODS
The Study Area
The present study was conducted in the Gongola Basin which forms part of
the Upper Benue Trough. The project started in June of 2002 and lasted to August
2004 covering and estimated area of 27390.25 km^{2} and lies between
longitude 10°00' and 11°30'E and latitude 09°30' and 11°00'N.
The central part of the study area (Fig. 2) is occupied by
the KerriKerri formation which extends up to the southwestern corner of the
map. The KerriKerri formation is believed to have a thickness of about 320
m. The Pindiga Formation, Bima sandstone, Yolde formation and Gombe sandstone,
occupy the Northeastern portion of the map and extend down to the Southeastern
part of the area. The Pindiga formation consists mainly of shaly mudstone with
intercalation of limestone occurring in some areas. The Pindiga formation is
believed to have a thickness of about 240 m. The Yolde formation on the other
hand has a thickness of about 200 m. The Yolde formation is indeed a transitional
sequence between the continental Bima group and the marine deposits of the lower
part of the Pindiga Formation. Gombe sandstone consists mainly of grits and
clay and is restricted to the western part of the Basin. The Bima sandstone
consists of coarse grain sandstone with an overall thickness of about 3500 m.
The crystalline basement rocks which occupy the extreme western portion of the
area, consist of scattered remenants of highly metamorphosed sedimentary rocks
and diverse, predominantly granitic plutonic masses collectively called older
granite (Carter et al., 1963).
The total magnetic field over the study area was obtained by digitizing nine
aeromagnetic maps of the Geological Survey of Nigeria (GSN) airborne geophysical
series sheets 129 (Ganjuwa), 130 (Dukku), 131 (Bajoga), 150 (Alkaleri), 151
(Akko), 152 (Gombe), 171 (Yuli), 172 (Futuk) and 173 (Kaltungo). The maps were
digitized along flight lines. The data obtained by the digitization of the various
maps are unequally spaced, while that is good in minimizing aliasing effecting
in sampled data (Bath, 1974), the data is not suitable
for most methods of quantitative interpretation. The method for interpolation
of these data in the present study is a method that combines Laplace interpolation
and that of quadratic weighting. A grid interval of 0.01 degree of latitude
and longitude were used to obtain a 51x51 data points. The gridded data were
then integrated and the data obtained is used to plot the composite map of the
study area. From the total magnetic field obtained, the residual magnetic field
over the area was calculated by removing a firstdegree regional field derived
by using a method of robust statistics described by Ojo
and Kangkolo (1997).

Fig. 2: 
Geologic map of the study area (after Benkhelil, 1989). Simplified
geological map of the Upper Benue Trough showing sample locations. 1: Quaternary
alluvium; 2: Tertiary volcanics; 3: Kerrikerri Formation; 4: Gombe Sandstone;
5: Pindiga Formaion; 6: Yolde Formation; 7: Bima Sandstone; 8: Burashika
Complex (Mesozoic volcanism); 9: Undifferentiated Basement Complex. Main
Fault zones; BL: Burashika Fault; KL: Kaltungo Fault; TL: Teli Fault (After
Benkhelil, 1989) 
The residual maps of the study area is shown in Fig. 3.
Spectral Analysis
The 2dimensional Fourier Transform pair may be written as (Bhattacharyya,
1966; Bath, 1974):
where, u and v are the angular frequencies in the x and y directions, respectively.
G (u, v), when broken up into its real and imaginary parts is given by:
The energy density spectrum or simply the energy spectrum is given by:

Fig. 3: 
Residual magnetic field intensity map of the study area (contour
interval 20 nT). Inserted are profiles taken for the modeling exercise 
Residual total magnetic field intensity values are used to obtain the twodimensional
Fourier transform from which the spectrum is to be extracted. The frequency
intervals are then further divided into subintervals, which lie within one
frequency range. The average spectrum of all the values falling within this
frequency range is calculated and the resulting value together constitute the
radial spectrum of the anomalous field.
A logarithmic plot of the power spectrum versus frequency on a linear scale
shows a series of points, that may well be represented by bodies occurring within
a particular depth range, which fall on one or more straight line segments whose
slopes provide a measure of the mean depth to the ensemble of anomalous bodies
(Spector and Grant (1970)). If z is the mean depth of a layer, the depth factor
for this ensemble of anomalies is .
Thus, the logarithmic plot of the radial average power spectrum would give a
straight line whose slope in2z. The mean depth of burial of the ensemble is
thus given by:
where, m is the slope of best fitting straight line. The above equation is
used directly if frequency units are in radians km^{1}, but for those
in cycles km^{1} is used:
Table 1: 
Depth in kilometers to the first, second, and third magnetic
levels for nine (9) blocks of 51 x 51 grid size 

The results have been corrected for flight height 
Spector and Grant method consistently overestimates depths over the range of
0 to 15 km (Fedi et al., 1997), while the use
of discrete Fourier transform introduces the problem of aliasing and the truncation
effect. Hence, the corrected power spectrum of Fedi et
al. (1997), was used in the present study to correct for depth overestimation.
While, digitizing the magnetic field data can reduce the aliasing effect, truncation
effect is reduced by applying a cosine taper to the observed data before Fourier
transformation (Bath, 1974). For the determination of
depths to magnetic layers using the spectral method, the study area was divided
into nine sections consisting of 51x51 grid size (or data points). Table
1 gives the locations of these sections with X_{1} and X_{2}
representing the limiting longitude values while Y_{1 }and Y_{2}
give the limiting latitude values. Each of these sections covers an estimated
area of about 54x54 km^{2}. The main aim of this part of the analysis
was to provide some guides in the starting depths to be used later in the modeling
exercise. The radial spectrum for each section was then evaluated in the manner
described above. Some of these graphs present two linear segments while others
present three segments. From the gradient of these segments the average depths
to the causative layers were determined and designated D_{1}, D_{2}
and D_{3} as the case may be.
Modeling
Several methods for modeling anomalous bodies have been developed over the
years. These methods include the twodimensional modeling (2D), the threedimensional
(3D) e.g., Talwani et al. (1959) and the 2½
dimensional modeling developed by Gemperle et al. (1991).
The twodimensional modeling techniques are often used or applied in modeling
elongated bodies with length to width ratio grater than 10, as in the case of
dykes, thus, the length is assumed to be infinite. In the 3D techniques, many
geometric forms have been used to model magnetic bodies. Some of these forms,
such as the vertical and inclined prism, have been particularly successful,
especially in near surface exploration work. The 2½D modeling technique
is an improvement of the 2D methods and an approximation to the 3D model.
In this method, the length is made finite though considerably longer than the
width of the body. The modeling technique applied to any survey depends on the
structure intended to be modeled and the purpose of the survey. Twodimensional
techniques may readily be used to model dykelike bodies, since, their length
to width ratio is usually greater than 10. 3D modeling techniques are easily
used in modeling batholiths, while moderately elongated slabs can be modeled
using the 2 ½D method (Gemperle et al., 1991).
In the present study, the aim was to model the shape and depth of the Gongola
Basin, along with structures of the basement and intrusions overlaid by the
basin. The GMSYS twoandhalfdimensional modeling technique satisfies the
need enumerated above for the present work. The GMSYS modeling programme, is
a programme used for the easy interactive modeling of a 2D and optionally 2½D
geologic crosssection with the ability to quickly calculate and display the
gravity and magnetic response from the crosssection. In this study, the 2½D
option was used. The method used in calculating the magnetic response and model
is based on the methods of Talwani et al. (1959)
and Talwani and Heirtzler (1964). The programme makes
use of algorithms described in Won and Bevis (1987).
The 2½D calculations are based on Rasmussen and
Pedersen (1979). Three profiles were selected for modeling covering the
anomaly as shown in Fig. 3. All the profiles were taken perpendicular
(i.e., NWSE) to the strike direction of the most prominent anomaly (i.e., NESW)
in order to obtain the best estimate of the parameters of the body from the
profiles taken. In modeling the profiles, the depth factor was initially estimated
by the results obtained from spectral analysis. Furthermore, the basin was assumed
to be underlain by granitegneiss, which is the dominant rock type of the basement
complex of Nigeria (McCurry, 1971). The choice of susceptibility
values used in this modeling was based on reported susceptibility ranges of
0.0090.0097 SI units (Ajakaiye, 1981), which have been
obtained for the Benue Trough (of which the present study area is part). The
GMSYS uses the Gaussian (CGS) system of units for magnetic quantities hence,
all values were converted to Gaussian units before input into the programme.
RESULTS
Spectral Analysis
The results of the Spectral analysis carried out is displayed in Table
1. The first layer depth (D_{1}) varies from 1.00 to 1.80 km with
an average value of 1.19 km, while that of the second layer depth (D_{2})
varies from 2.61 to 6.20 km with an average value of 3.16 km, the third layer
depth (D_{3}) varies from 3.51 to 8.03 km with an average value of 5.39
km.
2½D Modeling
Profile AA^{1
}A susceptibility of 0.012 SI units that represents an overall average
for the basement rocks as reported by previous workers, was used for the host
rock as a trial value. A susceptibility value of 0.364 SI units was needed for
the magnetic body to obtain a good fit. This value falls within the range of
values for basic rocks and basalt (Dobrin and Savit, 1988;
Telford et al., 1976).
The model (Fig. 4a, b) consists of a layer
of sedimentary rock with an assumed susceptibility of 0. The sediment thickness
on this profile reaches a depth of 3.38 km. Basement rocks underlie this sedimentary
layer with susceptibility of 0.012 SI units. The most prominent feature along
this profile is a high susceptibility body (of susceptibility 0.364 SI units),
which has a depth to the top of 3.08 and 8.05 km to the bottom. This is modeled
to be the cause of the prominent magnetic anomaly occurring at the central part
of the profile AA^{1}. The susceptibility also suggested that the source
of the body is a basic intrusion at depth within the crust, probably emplaced
during the rifting of the Benue Trough.
Profile BB^{1
}The model for profile BB’ is shown in Fig. 5a
and b. The susceptibility value of the host rock was kept
at i.e., 0.012 SI units while, a susceptibility value of 0.354 SI was required
for the intrusive rock to obtain a good fit.

Fig. 4: 
(a) Calculated and observed residual magnetic field along
profile AA^{1} and (b) model for profile AA^{1} 

Fig. 5: 
(a) Calculated and observed residual magnetic field along
profile BB^{1} and (b) model for profile BB^{1} 
The sediment thickness in this model reaches a maximum value of 4.50 km along
this profile, with depth to the top and bottom of the high susceptibility body
reaching 2.75 and 6.76 km, respectively.
Profile CC^{1
}The model for this profile is shown in Fig. 6a and
b. The susceptibility of the host rock was also maintained
at 0.012 SI while a susceptibility value of 0.312 SI units was required here
for the intrusive magnetic body to obtain a good fit. As can be seen, all the
values fall within the range of values for basic rocks.

Fig. 6: 
(a) Calculated and observed residual magnetic field along
profile CC^{1} and (b) model for profile CC^{1} 
The model also shows the sedimentary layer attaining a depth of up to 4.05
km. A depth of 1.37 and 8.09 km were obtained for the top and bottom of the
intrusion or the magnetic body, respectively.
DISCUSSION
Previous geophysical studies carried out in the area have suggested the existence
of nearsurface intrusion, volcanic plugs, basement rocks and/or basalt flow
which could be deeply rooted (Ofoegbu, 1984, 1988;
Ajakaiye et al., 1986; Ajayia
and Ajakaiye, 1981; Ofoegbu, 1986). Shemanget al., 2001 concluded after a 2dimensional modeling of magnetic data, that
there is the existence of basic intrusive at depths of 17 km at different points
in the trough and also the existence of marginal intrusion at depths of 12
km from the surface. Hence, the depth values obtained in this study of 11.80
km for the marginal intrusions appear to be quite logical. The slight differences
observed in the results could be attributed to the different methods used in
estimating these depths, for instance while, Shemanget al., 2001 used
Werner deconvolution to estimates these depths spectral analysis was used in
the present study.
Shemanget al., 2001 concluded after a 2dimensional modeling of some
magnetic anomaly in the Gongola Basin to be an old magmatic rift, the 2½dimensional
modeling used in the present study is an improvement over the 2dimensional
and also a short cut to the 3 dimensional methods. The method did not only suggest
the existence of basic intrusions at different depth in the basin but also mapped
out the basement topography which was seen to have a graben like structure.
The models suggests the existence of basic rocks of large extent at depths between
1.378.09 km. The source of the basic rocks could not be seen from the models
as they are completely embedded within the basement. This, however, suggest
that the source could be at a greater depth thereby suggesting the area to be
an old rift. According to Benkhelil, 1989, magmatic
activity in the upper Benue trough occurred in two major episodes. The first
episode took place in the Mesozoic and this includes the Burashika complex of
Jurassic age and the basaltic veins of Cretaceous age, restricted to faults
trending N55° (Carter et al., 1963). The
second phase occurred during the Tertiary, corresponding to the intense alkaline
magmatic activity in relation to the Cameroon volcanic line. This tertiary phase
of magmatic activity is seen to occur in form of Biu basalt (Fig.
1). The magnetic susceptibility for the intrusions from the present study
suggest a value ranging from 0.312 to 0.364 SI units, suggesting that they are
basic to ultrabasic in composition thus, indicating that they are mantle derived
(probably volcanic). The existence of these two major episodes of magmatism
in areas adjacent to the study area (Burashika complex and Biu plateau) and
especially the Tertiary episode which outcrops in the area in the form of basalts
(Biu basalts) strongly suggest that the basic rocks observed at depth in the
area of study are a product of volcanism at depth in the area.
CONCLUSION
From the results obtained, it can be said that the Gongola Basin evolved through a combination of different processes, first there was mantle upwelling or rise of a mantle plume which resulted Crustal stretching and thining as observed by the linear nature of the modeled anomaly. There was block faulting in the area as the basin tends to show a graben like structure. The emplacement of basic igneous material in the crust then follow with some not reaching the surface but, were trap within the basement rocks as seen from the model and also within the sediments and consequently rifting.
ACKNOWLEDGMENTS
Author would also like to acknowledge (IPPS) Uppsala, Sweden for providing the software used for the Modeling exercise. Author would also like to acknowledge the financial support of the Ahmadu Bello University board of research grant No. DAPM/BOD/06 for this research.