609_620 Assran20.pdf


ANNALS OF GEOPHYSICS, VOL. 45, N. 5, October 2002

609

Application of ground magnetic
and multi-frequency EM techniques for

the Abu-Shihat radioactive prospect area,
North Eastern Desert, Egypt

Assran S.M. Assran
Nuclear Materials Authority, Cairo, Egypt

Abstract
Land magnetic and electromagnetic data enhancement procedures were employed to follow the extensions of the
observed anomalies on the surface downwards in the deeper levels and to recognize any possible relations between
the localization of uranium mineralization and both the structural and geologic settings. This study revealed that
the Analytic Signal (AS) and high pass and low pass filtering approaches significantly improve the interpretability
of the measured magnetic data in discriminating the shallow and deep magnetic sources within the Abu-Shihat
prospect area. Furthermore, the EM survey using varying frequencies, coil separations and station separations
was performed in the considered area with the horizontal-loop EM equipment. The interpretation of the horizontal-
loop EM data indicated the presence of some conductive zones. These zones are mainly associated with felsite
and pegmatite dykes, as well as alteration and fault zones. The target parameters such as the location, width,
depth, dip and conductivity thickness were estimated for each conductive zone. Combining the ground magnetic
and horizontal-loop EM surveys with the geological and structural mapping revealed that the mineralizations are
concentrated in the eastern and western parts of the study area, and these techniques are considered as valuable
exploration tools for uranium associated sulfide mineralization.

1.  Introduction

The Abu-Shihat prospect area (26°38′N,
33°24′E) is located about 8 km north of Qena-
Safaga road at El-Faroukiya station (85 km from
Qena). The Nuclear Materials Authority (NMA)
selected it through intensive geological, geo-
chemical and geophysical studies.

Mailing address: Dr. Assran S.M. Assran, Nuclear
Materials Authority, P.O. Box 530, Maadi Road Post Office,
Cairo, Egypt; e-mail: assran@hotmail.com

Key  words  magnetic – analytic signal – wavelength
filter – multi-frequency EM – geological mapping

The geophysical investigation started by
aerial radiometric and magnetic survey for the
area bounded between latitudes 25°48′N and
26°44′N and longitudes 32°53′E and 33°34′E
(Ammar, 1973), including the present prospect
area (fig. 1). This investigation was followed by
ground proving and checking of the recorded
anomalies, accompanied by regional geological
investigations, followed by semi-detailed and
detailed radiometric investigations (El-Tahir,
1978; Bakhit et al., 1984).

The results of the previous radiometric and
geochemical studies had identified three anom-
alous radiometric zones in the study area (El-
Tahir, 1978). Each of these locations was ex-
cavated with a front-loader. A relative increase
in the uranium mineralization was found, mainly



610

Assran S.M. Assran

represented by secondary uranium minerals and
some sulfide minerals in the highly fractured
granites and granodiorites, as well as the felsitic
and pegmatitic dykes. The radioactivity is ranged
from 80 to 320 Ur at the surface, with a maxi-
mum of 480 Ur at about 1 m depth. El-Tahir
(1978) recommended further geophysical and
drilling investigations in a trial to discover any
subsurface extensions of the uranium miner-
alizations.

Magnetic and electromagnetic techniques
have historically been the most common geo-
physical methods used in mineral exploration.
Both techniques are cost effective and the data
can be interpreted quickly in the field. Often,
the data resulting from the two methods are suffi-
cient to characterize the buried targets (Won
and Keiswetter, 1997). The present work deals
with the application of ground magnetic, multi-
frequency and multi-separation EM survey,

besides detailed geological mapping for the study
area, to follow the extensions of the observed
anomalies in the deeper levels, and to recognize
any possible relations between the EM anoma-
lies and magnetic anomalies, as well as the com-
parable geologic settings.

2.  Geologic setting

The regional geology, structural set-up and
potentialities of uranium in the Abu-Shihat area
have been discussed by many workers (Schur-
mann, 1966; Sabet et al., 1972; Ghanem et al.,
1973; El-Tahir, 1978; Bakhit et al., 1984). The
author carried out a detailed geologic mapping
for the prospect area (fig. 2). Accordingly, the
study area is formed mainly of Precambrian
basement rocks including quartz diorites, gra-
nodiorites and granites. These rocks are injected
into the area by numerous pegmatitic, felsitic,
quartzitic and basic dykes, and are locally cov-
ered by Quaternary sediments, which are re-
presented by wadi (valley) sediments. These
rocks were exposed to different tectonic events
that produced various secondary structural
elements as faulting and shearing in the N-S,
NE-SW, ENE-WSW and NW-SE directions,
beside the other minor trends.

3.  Ground magnetic survey

3.1.  Magnetic data acquisition and correction

A total magnetic field intensity survey was
performed on a set of parallel N60°W profiles
normal to the general strike of the mineralized
felsite dykes. The line spacing was 50 m and
the measurements were taken at 20 m intervals
along the survey profiles. Two tie lines were
conducted (coded 00 and 300) normal to the
observed profiles for controlling the consistency
and reliability of the data. Two proton magnet-
ometers (model PMG-1, Geofyzika, Brno,
Czech Republic) were used: one for mobile
station readings and the other for the base station
readings. Base station readings were recorded
every 30 s and used to correct for diurnal drift.
The corrected values were then reduced to an

Fig. 1. Key map showing the location of the Abu-
Shihat radioactive prospect area, North Eastern Desert,
Egypt.



611

Application of ground magnetic and multi-frequency EM techniques for the Abu-Shihat radioactive prospect area, ...

arbitrary datum (41 800 nT) and the resulting
data used to generate a total intensity magnetic
map (fig. 3).

3.2.  The total intensity magnetic map

According to the visual inspection of the total
magnetic map (fig. 3), three magnetic zones of
various magnetic characteristics were distin-
guished on the basis of the differences in the
character of the magnetic anomalies i.e. their
wavelengths, amplitudes and trend patterns. The
first zone (Z1) covers the western and north-
western parts of the study area and is associated
with felsite, quartz dykes and diorite rocks. It is
occupied by broad belts of low frequencies
having nearly a NNW-SSE direction. This zone

decreases gradually in magnitude towards its
western part, where its amplitude reaches – 95
nT. The second zone (Z2) is situated at the central
part of the area and is characterized by a group
of relatively strong positive anomalies with a
maximum amplitude of about 318 nT. These
anomalies are associated with the basic dykes
and diorite rocks (fig. 2). They trend in the N-S,
NNE-SSW and NW-SE directions. The third
zone (Z3) is located at the eastern part of the area
and is associated with the pink granites and
granodiorites. The northern part of this zone is
represented by negative and positive closures of
relatively small sizes and varying amplitudes,
which may indicate that the causative bodies
might be exiting at shallow depths. Meanwhile,
the southern part is occupied by a negative rec-
tangular belt and is divided into small negative

Fig.  2.  Detailed geological and structural map of the Abu-Shihat radioactive prospect area, North Eastern
Desert, Egypt, showing the 3 lines selected for EM survey. Symbols are: 1 = wadi sediments; 2 = basic dykes;
3 = quartz dykes; 4 = felsite dykes; 5 = pegmatite dykes; 6 = pink granites; 7 = granodiorites; 8 = diorites;
9 = alteration zones, and 10 = fault.



612

Assran S.M. Assran

anomalies trending mainly in the N-S and E-W
directions. This may indicate the existence of
small separate magnetic bodies resting over a
deeper one.

3.3.  Analytic signal map

The Analytic Signal (AS) has been shown
to be effective in interpreting the subsurface
magnetic contacts (e.g., Nabighian, 1972, 1974).
This method does not require reduction to pole
processing. A geologic contact or fault with sig-
nificant susceptibility contrast is detected by
mapping the maxima of the simple analytic
signal, which is composed of two horizontal and
one vertical gradients (Nabighian, 1972, 1974,
1984; Roest et al., 1992). Visual inspection of
the analytic signal map (fig. 4) exhibits a number
of maxima that conform very well with to the
structural trends and geologic rock boundaries.

The western part of the map is occupied by
relatively low frequency anomalies, which may
reflect the deep sources at this part and also
confirm  the results obtained from the total in-
tensity magnetic map (fig. 3). The small highs
within this part are associated with felsite and
pegmatite dykes, where each peak corresponds
to one of the dykes appears. Meanwhile, the
eastern part is characterized by high anomalies,
which generally coincide with pink granites.
Also, it seems obvious from the southeastern part
that, the pink granites and granodiorites have
small highs within a larger one. This may reflect
a wide aerial extent below thin veneers of the
rocks at this part. These high anomalies are
separated by relatively low amplitudes and are
associated with diorites (fig. 2). Therefore, from
the above mentioned considerations, it can
be concluded that the AS is a very good tool
that can be used in differentiating the various
rock types and delineating the structural trends

Fig.  3.  Total intensity magnetic map of the Abu-Shihat radioactive prospect area, North Eastern Desert,
Egypt.

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613

Application of ground magnetic and multi-frequency EM techniques for the Abu-Shihat radioactive prospect area, ...

that may be obscured in the total intensity mag-
netic map.

3.4.  Regional-residual separation

Magnetic data observed in geophysical sur-
veys are the sum of magnetic fields produced
by all the underground sources. The targets for
specific surveys are often small-scale structures
that occurred at shallow depths. The magnetic
responses of these targets are embedded in a re-
gional field, which arises from magnetic sources
usually larger or deeper than these targets. Cor-
rect estimation and removal of the regional field
from the initial effect yields the residual res-
ponse produced by the target sources.

In the present study, the Fast Fourier Trans-
form (FFT) was applied on the total intensity
magnetic data using Geosoft Package (1994) to
explore the frequency content of these data. As

a result of visual inspection of the two-dimen-
sional power spectrum (fig. 5), two linear
segments were distinguished and fitted. The first
segment lies at the low frequency (long wave-
length) with a steep slope, related to the deep
and/or broad causative magnetic sources. Mean-
while, the second segment is located at high
frequency (short wavelength) with a gentle slope
and is due to relatively shallow sources. The
slope of a line fitted to each of the first and
second segments of the spectrum curve is used
to estimate the average depths of the regional
and residual sources. These depths were re-
computed with the power-low correction (Fedi
et al., 1997). The estimated average depths to
the regional and residual sources are 53.1 and
12.4 m, respectively. Moreover, the analysis of
the power spectrum curve shows that the deep-
seated magnetic component frequency varies
from 0 to 6 cycles/km, while the near-surface
magnetic component frequency ranges from 6

Fig.  4.  Analytic signal of the total intensity magnetic map of the Abu-Shihat radioactive prospect area, North
Eastern Desert, Egypt.

    



614

Assran S.M. Assran

Fig.  5.  Radially averaged power spectrum and depth estimate of the total intensity magnetic map of the Abu-
Shihat radioactive prospect area, North Eastern Desert, Egypt.

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Fig.  6.  High-pass filtered (frequency = 6-65 cycles/km) magnetic map of the Abu-Shihat radioactive prospect
area, North Eastern Desert, Egypt.

    



615

Application of ground magnetic and multi-frequency EM techniques for the Abu-Shihat radioactive prospect area, ...

to 65 cycles/km. These bands of frequency were
used through the band-pass filter technique to
produce the residual and regional component
maps (figs. 6 and 7).

3.4.1.  The high-pass (residual) magnetic
anomalies

The residual magnetic anomalies can be
defined as the anomalies that are economically
interesting, because they indicate shallow anom-
alies and are characterized by weaker and more
localized anomalies. The high-pass filtered map
(fig. 6) reveals that the study area is charac-
terized by small closures with semicircular to
circular shapes and relatively high positive and
negative amplitudes. The causative bodies of
these closures might be cropped out or buried at
shallow depths. Besides, relatively broad
anomalies of deeper origin with low slopes and

smooth shapes having relatively low am-
plitudes were seen. The residual anomalies are
frequently preferred in the N-S, NW-SE and
NE-SW directions and most of them are not
shown clearly on the total intensity magnetic
map (fig. 3).

3.4.2.  The low-pass (regional) magnetic
anomalies

The regional magnetic anomalies are strong,
broad, extend over large areas and usually have
high amplitudes and low frequencies. These
anomalies are of considerable significance in the
regional tectonic studies of the basement com-
plex and of secondary importance in mineral
exploration. The low-pass filtered map (fig. 7)
shows:

1)  A huge zone of high magnetic anomalies
at the central part of the study area, bounded from

Fig.  7.  Low-pass filtered (frequency = 6-65 cycles/km) magnetic map of the Abu-Shihat radioactive prospect
area, North Eastern Desert, Egypt.

    



616

Assran S.M. Assran

the west, north and east by relatively steep mag-
netic gradients. This may suggest the existence
of major deep-seated faults bounding this zone
from the stated directions.

2)  A broad negative magnetic anomaly lo-
cated at the southeastern corner of the study area,
approximately trending in a N-S direction and
associated with the pink granites and grano-
diorites.

3)  A negative magnetic belt located at the
northwestern part, trending in the NNW-SSE
direction and associated with a set of felsite and
quartz dykes. This may suggest that, these dykes
are relatively deep at this part.

4)  The regional magnetic anomalies are
elongated mainly in the N-S, NNE-SSW and
E-W directions.

4.  Horizontal-loop electromagnetic survey

The electromagnetic (EM) induction method
can be used to infer the electrical conductivity
of the subsurface at different depths of interest by
changing the spacing between transmitter and
receiver coils or the frequency of the transmit-
ted field (Patra and Mallick, 1980; Won, 1980;
Keiswetter and Won, 1997). The horizontal-loop
electromagnetic (HLEM) method is based on the
principle of inducing eddy currents in the earth
with a transmitter coil (Tx), which generates a
primary electromagnetic field. The strength of the
induced current and consequently that of the
secondary electromagnetic field is dependent on
the conductivity, shape and size of the target body
and its location relative to the transmitter-receiver
positions. The in-phase and out-of-phase com-
ponents of the resulting secondary electromag-
netic field are recorded at frequencies 112.5,
337.5, 1012.5 and 3037.5 Hz. The coil separation
between the transmitter coil (Tx) and receiver coil
(Rx) was either 100 or 120 m. The midpoint of
the line joining the Tx-Rx is used as the meas-
uring point. The HLEM measurements were ac-
quired at station spaced 10 and 20 m apart along
the survey line, using the TM-2 transmitter and
IGS-2/EM-4 receiver (Scintrex Limited, Canada).

By judicious application of the multi-fre-
quency techniques, it is possible to detect the
weaker conductors (small width) and to derive

detailed information on the parameters of the
conductors, from the anomalies obtained with
the HLEM method. Besides the detection of
electromagnetic anomalies, the aim of an elec-
tromagnetic survey is to estimate the parameters
of the causative conductors from details of the
gained anomalies. The main characters of the
HLEM interpretation are, the location, dip (θ ),
width (w), depth of burial (h) and conductance
(σ t). These parameters can be estimated by using
a family of response diagrams and curves, which
were designed by Nair et al. (1974). The first
step in interpreting the HLEM data is to establish
the background in-phase and out-of-phase values,
away from the anomaly to be interpreted. Ac-
cording to the results formerly obtained from the
radiometric and geochemical data (El-Tahir,
1978), the HLEM survey was conducted along
three profiles (coded 200, 300 and 1200). The
HLEM data, corrected for the first-order topog-
raphic effects, are shown in figs. 8, 9 and 10.
The examination of these profiles led to the
following observations.

4.1.  Line 200 (A-A′)

This profile was conducted between stations
– 250 and 210 with coil separations 100 and
120 m, and station intervals 20 and 40 m. The
HLEM data shown on this line (fig. 8) indicate
the existence of two EM anomalies. The first is
close to station – 190 and is associated with the
pegmatite body (fig. 2). The width of this
anomaly is less than the coil separation and may
be due to a thin conductor. The second one has a
negative peak for the in-phase and out-of-phase,
and extends from about station coded – 40 to
about station coded 100. This anomaly coincides
with a set of faults and an alteration zone, as
shown on the geologic map (fig. 2).

The results of quantitative interpretation of
the second anomaly are the width that is about
40 m, the depth to the upper edge that attains
52 m and the approximate dip angle that reaches
60° to the south. Meanwhile, a considerable in-
crease in the conductance estimates was observed
by decreasing the frequency from 12.1 mhos at
3037.5 Hz to 47.6 mhos at 112.5 Hz. This effect
is due to the body thickness and the current



617

Application of ground magnetic and multi-frequency EM techniques for the Abu-Shihat radioactive prospect area, ...

gathering, a conclusion also supported by the
results obtained by Betz (1975, 1976) for ground
EM measurements and by Palacky (1978) for
airborne EM surveys. Comparing the estimated
depth, dip and conductance measured using the
coil separations 100 and 120 m, they are highly
similar, but the width estimates increase with
increasing spacing. This effect can be explained
by the fact that, the values of the in-phase and
out-of-phase components are primarily affected
by dimensions of the conductor being investi-

gated and its position in relation to the coil po-
sitions and coil separation.

The first EM anomaly coincides with low
magnetic amplitudes and high frequencies
(figs. 3, 4 and 7). This may indicate that, the
causative body lies within shallow depths. Also,
the second EM coincide with low magnetic
amplitudes and low frequencies (figs. 3, 4, 6 and
7). This may reveal that, the causative body is
relatively deep at this part. The estimated depth
of the second anomaly agrees well with the
average depths of the deep magnetic anomaly
sources. Because of the high radiometric values
(El-Tahir, 1978) in this zone, which is associated
with the high conductance and low magnetic
values at this part, a more detailed ground survey
of this zone is recommended.

4.2.  Line 300 (B-B′)

This profile was carried out between stations
– 270 and 90, with coil separation 100 m and
station interval 20 m. Only one broad conductive
zone is indicated by a negative peak that extends
from about station – 220 to about station – 60
(fig. 9). This zone corresponds to the extension
of a geologically-mapped felsite dyke and the
intersecting faults (fig. 2). The shapes of the in-
phase and out-of-phase components suggest two
conductors spaced 60 m apart, as the maximum
negative peak values are separated by more than
coil spacing of 60 m. The northern shoulder of
the in-phase and out-of-phase components is
reduced appreciably at higher frequencies, indi-
cating the existence of conductive bodies in this
region. This is supported by the magnetic and
radiometric data. Other researchers observed a
reduction of the out-of-phase component in the field
and modeled EM data (Lajoie and West, 1977).

The quantitative interpretation of the HLEM
data exhibits the width of the conductive zone
as 60 m, the dip angle as 32° to the north, the
depth to the upper edge attains 18 m and the
conductivity thickness increases with decreasing
frequency. It ranges from 4.8 to 22 mhos. This
effect is due to the causative overburdens, which
may cause phase rotations of the anomaly, resul-
ting in the estimates of conductivity thickness
decreasing with increasing frequency.

Fig.  8.  Horizontal-loop EM profiles at several fre-
quencies, coil separations and station separations with
the corresponding total magnetic field profile along
line A-A′ (line 200) and surface geology of the Abu-
Shihat radioactive prospect area, North Eastern Desert,
Egypt. Symbols as in fig. 2.



618

Assran S.M. Assran

On the high-pass filtered map (fig. 6), the EM
conductive zone is represented by two belts of
high frequencies and low magnetic amplitudes
intruded by a belt of high magnetic amplitudes.
Also, the low magnetic amplitudes coincide with
the negative peaks of the in-phase and out-of-
phase components. This may suggest that, two
acidic causative bodies lie within the shallow
depths.

4.3.  Line 1200 (C-C′)

This profile was conducted between stations
– 190 and 490, with coil separations 100 and
120 m, and station intervals 20 and 40 m. The
examination of HLEM data acquired along this
line with coil separation 100 m exhibits a broad
conductive zone at the northern part (fig. 10).

The shapes of the negative and positive peaks of
the two components reveal that this zone is
composed of a series of thin conductors over a
width greater than 130 m of the coil spacing. On
the magnetic maps (figs. 3 and 5), this zone is
characterized by a group of relatively low mag-
netic amplitudes and high frequencies. This may
reflect the causative bodies as acidic rocks, that
lie within relatively shallow depths. Geo-
logically, this zone coincides with a set of faults
and felsite dykes (fig. 2).

The general parameters of the considered
conductive zone (Tx-Rx = 100 m) show that the
width is about 130 m, the depth to the upper edge
reaches 26 m, the dip angle is 62° to the south

Fig.  9.  Horizontal-loop EM profiles at several fre-
quencies, coil separations and station separations with
the corresponding total magnetic field profile along
line B-B′  (line 300) and surface geology of the Abu-
Shihat radioactive prospect area, North Eastern Desert,
Egypt. Symbols as in fig. 2.

Fig.  10.  Horizontal-loop EM profiles at several fre-
quencies, coil separations and station separations with
the corresponding total magnetic field profile along
line C-C ′ (line 1200) and surface geology of the Abu-
Shihat radioactive prospect area, North Eastern Desert,
Egypt. Symbols as in fig. 2).



619

Application of ground magnetic and multi-frequency EM techniques for the Abu-Shihat radioactive prospect area, ...

and the conductivity thickness ranges from 3.8
mhos at 3037.5 Hz to 34.2 mhos at 112.5 Hz.
Meanwhile, the HLEM data with coil separation
120 m shows the existence of a broad and in-
complete anomaly, whereas only one positive
peak is present and the other one is outside the
survey area. Besides, some of the anomalies in
the in-phase and out-of-phase components are
lost. This is often by apparent loss, because the
smaller separation discriminates more effectively
between the conductivities. Also, the positions
of the peak values for the two components differ
markedly, which may indicate that the observed
anomaly represents the combined effect of two
or more sources.

5.  Conclusions

The visual inspection and analysis of the total
intensity magnetic map and the other filtered
magnetic maps revealed that the area concerned
is generally characterized by a broad and high
magnetic belt at the central part surrounded by
low magnetic belts from the east and west.
Besides, it includes surficial or local anomalies
of shallow-seated origin, with narrow semicir-
cular to circular shapes of relatively high ampli-
tudes having N-S, NW-SE and NE-SW di-
rections. The average estimated depth for the
near-surface magnetic anomaly sources of the
area is 12.4 m, while that of the deep-seated
anomaly sources is 53.1 m.

The investigation of the horizontal-loop elec-
tromagnetic profiles reflected the occurrence of
many conductive zones. These zones are mainly
associated with a set of felsite dykes, alteration
and fault zones. The conductive parameters, as
estimated from the small coil separation and
station interval, revealed widths ranging between
40 and 130 m, shallow depths varying from 18
to 52 m, dip angles ranging between 32° and 62°,
and conductivity thickness varying from 22 to
47.6 mhos for the mineralized zones. Comparing
these values with the estimated values using
larger coil separation and station interval, they
are highly similar, but the width estimates in-
crease with increasing spacing. This effect can
be explained by the condition that the values of
the in-phase and out-of-phase components are

primarily affected by the dimensions of the
conductor being investigated and its position in
relation to the coils positions and coil separation.
Besides, when large spacing is used, some of the
anomalies are lost and the resolution of the
individual conductor becomes poor, and if more
than one conductor occurs, the interpretation of
the results becomes difficult.

Because of the high radiometric anomalous
zones, associated with the high conductive and
low magnetic values, a more detailed ground
survey of these zones and subsequent exploration
drilling, based on the geophysical data are rec-
ommended to test the depths and grades of the
probable mineralizations.

Acknowledgements

I would like to thank Professor Ahmed A.
Ammar for fruitful discussions and valuable
comments.

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(received March 15, 2002;
accepted October 22, 2002)