801

ANNALS  OF  GEOPHYSICS,  VOL.   51,  N.  5/6,  October/December  2008

Key  words  Electric properties – complex conductivity 
– frequency – hematite – water saturation

1. Introduction

Electrical spectra of porous rocks in the low 
frequency range reflect numerous polarization 
processes resulting mainly from rock heteroge-
neity. The first is the Maxwell-Wagner polariza-
tion (Mendelson and  Cohen, 1982) due to dif-
ferences in the electric bulk properties of rock 
components. Maxwell-Wagner theory allows 
the prediction of electrical spectra of mixtures 
from bulk partial volumes, the properties of 
their components and their microstructure. 
However, the Maxwell-Wagner theory was un-

able to explain the anomalously large polariza-
tion in water-bearing rocks at low frequencies. 
The problem is that the mixture theory does not 
take into account surface conductivity and po-
larization, as well as clustering of components 
in disordered mixtures. The surface conductivi-
ty (in S) of a mineral grain is defined as the 
anomalous conductivity existing in the close 
vicinity of the mineral surface and integrated 
over the electrical double-layer thickness (Leroy 
and Revil, 2004). Surface conductivity is fre-
quency dependent. Surface conductivity has two 
contributions; one is associated with the Stern 
layer and one with the diffuse layer in which 
counter-ion density obeys a Boltzmann distribu-
tion. None of these contributions can be ne-
glected but the Stern layer contribution domi-
nates.

This paper studies the A. C. electrical con-
ductivity and dielectric constant of a partially 
and fully saturated hematitic sandstone sample 
(Aswan area, Egypt) in the frequency range 
from 0.1 Hz to 100 KHz. This geological mate-

Relation between electric properties  
and water saturation for hematitic  

sandstone with frequency

Mohamed Mahmoud Gomaa
National Research Centre, Geophysical Sciences Dep., El-Tahrir St. Dokki, 12311, Egypt

Abstract
This paper focuses on the effect of water saturation on A. C. electrical conductivity and dielectric constant of 
fully and partially saturated hematitic sandstone sample (Aswan area, Egypt). The saturation of the sample was 
changed from partial to full saturation. Complex resistivity measurements at room temperature (~16°C), were 
performed in the frequency range from 0.1 Hz to 100 KHz. Experimental electrical spectra indicate, generally, 
that the electrical conductivity and dielectric constant vary strongly with water saturations and frequency. The 
low frequency electrical conductivity and dielectric constant are mainly controlled by surface conduction and 
polarization of the electrical double layer. The behaviour of the electrical conductivity and dielectric constant, 
with increasing water content, were argued to the orientational polarization of bound water for very low satura-
tions, displacement of the excess surface charges for relatively low saturations, and free exchange of excess ions 
in double layer with the bulk electrolyte and generation of transient diffusion potentials which lag behind the 
applied field for high saturations.

Mailing address: Dr. Mohamed Mahmoud Gomaa, 
National Research Centre, Geophysical Sciences Dep., El-
Tahrir St. Dokki, 12311, Egypt.; e-mail: mmmsgomaa@
yahoo.com



802

M. M. Gomaa

1) Adsorption water that can be adsorbed 
by soil particle from the air. It consists of a 
monomolecular layer around negatively 
charged mineral surfaces and additional tightly 
and loosely bound adsorption water layers 
(Mitchell, 1992).

2) Capillary water: It is the moisture in soil 
which is not bound around grains, but does not 
respond to gravity.

3) Free water: is attracted to the soil solids 
so loosely that it may respond to the pull of 
gravity and move downwards.

The addition of a small amount of water 
causes dramatic increases in the values of die-
lectric constant and conductivity. The adsorbed 
liquid forms at first mono- or polylayer islands. 
As saturation increases, continuous fluid films 
are formed on the grain surface. If water mole-
cules form strong bonds with the surface so that 
they cannot migrate in an electrical field, the 
most probable polarization mechanism is the 
orientation polarization of adsorbed water mol-
ecules or reversible hopping of H ions along the 
surface (Chelidze and Guéguen, 1999; Chelidze 
et al., 1999).

2.  Background on polarization phenomena 
of porous media

The physical mechanism of the polarization 
of adsorbed layers can be either the orientational 
polarization of dipole molecules of water or the 
transfer of charges (ions in the Helmoholtz or 
diffuse double layer or protons) along hydroxilic 
groups or chains, so-called surface charge trans-
fer complexes (Chelidze and Guéguen, 1999; 
Chelidze et al., 1999).

Pride (1994) referred to the mechanism of 
surface proton conduction, and he concluded 
that the hydrogen ions may efficiently conduct 
through the network of hydrogen-bonded water 
molecules present in the adsorbed layer, but he 
ignored this mechanism in his analysis.

The mechanism of polarization due to for-
mation of a physically adsorbed multilayer of 
water is much more effective than the orienta-
tional polarization of dipoles and results in high 
experimental values of dielectric constant; 
which are larger than the largest dielectric con-

rial is an example of a multi-component sys-
tem, a sand/hematite/water/air system. The 
concentration of the sample is mainly sand 
(~60%) with hematite (~40 %). The grain size 
of sand in the sample is in the order of ~60 
micrometer and the hematite is in the form of 
pigment. The porosity of the sample was calcu-
lated to be (~23%).

The aim of this work is to study the effect of 
water on the electrical conductivity and dielec-
tric constant of the sample and to try to find out 
the main conduction mechanisms that are re-
sponsible for the measured behaviour. The 
sample was chosen as an example of the com-
posite material that does not have a chemical 
reaction at the surface like clay, so the only sup-
posed response may be argued only due to the 
addition of water. The study of the electrical 
properties of the sample may be of good impor-
tance in the application of spectral induced po-
larization in the field and in the interpretation of 
dielectric and conductivity spectroscopic meas-
urements (A. C. electrical conductivity and di-
electric constant).

The components of the wet hematitic sand-
stone interact strongly to affect the electrical 
behavior of the mixture. Dry rocks without a 
metallic component at room temperatures are 
good dielectrics with conductivity of the order 
of 10-10 S/m and a relative dielectric constant of 
the order of several units. For partially and 
fully saturated rocks the water-rock interfaces 
give rise to large values of dielectric constant 
and strong frequency dependence (Chelidze 
and Guéguen, 1999; Chelidze et al., 1999) 
which can be explained by surface conduction 
and polarization processes. In the absence of an 
applied electric field, ions form a double layer 
at the water-rock interface. When an oscillating 
electric field is applied, the ions polarize around 
the rock grains giving rise to large dipoles and 
to large apparent dielectric constants (Chelidze 
and Guéguen, 1999;  Gomaa, 2004). As the 
frequency increases, ions have less time to 
travel to polarize and contribute more to the 
conductivity, since they are more in phase with 
the applied oscillating electric field.

Saarenketo (1998) suggests that water in 
soils can be classified according to its electrical 
properties as: 



803

Relation between electric properties and water saturation for hematitic sandstone with frequency

around the particles by an electric field. The 
displacement of counter-ions in the double 
layer is shown to be equivalent to the existence 
of a surface capacitance displaying a diffusion- 
controlled relaxation. This effect can be ex-
pressed by an additional apparent dielectric 
constant of the particles, exceeding their actual 
dielectric constant at low frequencies by many 
orders of magnitude. A distribution of the acti-
vation energies of the counter-ion particle 
movement on the particle surface is introduced 
to account for the relaxation spectrum of the 
dispersion curves.

Chelidze et al. (Chelidze and Guéguen, 
1999; Chelidze et al., 1999) discussed the «gi-
gantic low frequency polarization» theory 
(GLFP) caused by polarization of the electrical 
double layer (EDL) at the solid–liquid inter-
face. The GLFP theory allows for a free ex-
change of EDL excess charges with the electro-
lyte (polarization). Application of an electric 
field distorts the EDL due to migration and dif-
fusion of charges in it, which results in the ap-
pearance of local clouds with the excess of 
positive charges on one side of the particle and 
with their deficit on the other side within the 
bulk electrolyte, so concentration gradients 
near the particle appear, outside the EDL, in 
addition to the electric polarization field of the 
deformed EDL. However, steady-state polari-
zation due to the induced concentration gradi-
ents is established controlled by diffusion over 
distances of the order of the linear dimension of 
the particle. The conduction currents lag behind 
the applied field, which appear as displacement 
currents and seen experimentally as high values 
of the dielectric constant. This results due to the 
large electric charge of a particle, and the large 
electrolyte conductivity.

Chew and Sen (1982) studied the dielectric 
constant and conductivity of a dilute immobile 
ensemble immersed in an electrolytic solution. 
They concluded that the existence of double 
layer greatly enhances the counter-ion current 
in the double layer region in the presence of an 
external field. This counter ion current piles up 
charges at the polar ends of the particle, which 
discharge into the bulk solution through a diffu-
sion process in addition to a conduction proc-
ess. The diffusion current in the diffusion cloud 

stant of the mixture components (here hematite, 
sand, water or air). At low humidity, defect sites 
on grain surface present a high local charge 
density and a strong electrostatic field, that 
promote water dissociation providing protons 
as charge carriers of the hopping transport 
mechanism. Subsequent layers of water mole-
cules are physically adsorbed. Charge transport 
occurs when H 3O[ ]

+  releases a proton to a 
neighboring water molecule which accepts it 
while releasing another proton, and so forth 
(Grotthuss chain) (Garrouch, 2001; Garrouch 
and Sharma, 1994; Garcia-Belmonte et al., 
2003). At high humidity, liquid water condens-
es in the pores, and electrolytic conduction 
takes place along with protonic transport in the 
adsorbed layers.

The contribution of surface processes to the 
ohmic conductivity of porous systems is consid-
ered by (Glover et al., 1994a; Pride, 1994; 
Dukhin, 1971; Glover et al., 1994b). Also, mod-
eling of surface conductivity from the modeling 
of the electrical double layer combined with 
complexation of the surface sites is due to (Re-
vil and Glover, 1998) for silica and Leroy and 
Revil (2004) for alumino-silicates. Revil and 
Glover (1998) give a value of the specific sur-
face conduction associated with proton transfer 
in pure water to be 2.4 × 10-9 S  and examined 
the dependence of the surface conduction on 
salinity. Surface migration and diffusion evoke 
polarization mechanisms, which are often much 
stronger than the mixture component polariza-
tion (Chelidze and Guéguen, 1999; Chelidze et 
al., 1999).

Revil and Glover (1998) concluded that the 
contribution of the electrical diffuse layer to the 
surface conductivity can be neglected for silica 
and alumino-silicates, and that the main contri-
bution to surface conductivity is probably due 
to counterions located in the Stern layer with 
surface mobilities approximately ten times 
smaller than in the bulk electrolyte. Another 
contribution is related to the proton transfer di-
rectly on the mineral surface and is salinity in-
dependent.

Schwarz (1962) proposed that at low fre-
quencies the dielectric dispersion (for colloidal 
particles suspended in electrolytes) is due to the 
polarization of the counterion atmosphere 



804

M. M. Gomaa

been shown in studies by Knight (Knight and 
Nur, 1987; Knight and Endres (1990). In these 
studies the real part of the dielectric constant 
of sandstone samples was measured as the 
level of water saturation was varied. The fre-
quency range of the measurements was from 
60 kHz to 4 MHz. There was a general in-
crease in the electrical conductivity and dielec-
tric constant of the rock sample with the in-
crease of water. They showed that there may 
be a critical saturation point for water wet sam-
ples, below which the conductivity increases 
gradually with saturation and above it the con-
ductivity increase more slowly. They observed 
a power-law dependence of the dielectric con-
stant (e) on the frequency (w). They related the 
power law exponent to the water saturation 
and the surface area to volume ratio of grains. 
The power law response is thought to be due to 
the random nature of the constituents within 
the samples (Jonscher, 1999; Gomaa et al., 
2000). 

Chelidze et al. (Chelidze and Guéguen, 
1999; Chelidze et al., 1999) gave an explanation 
for the large low-frequency polarization of the 
fully saturated rocks that it takes into account 
the heterogeneity in the distribution of the elec-
trical charges on the mineral surfaces. In this 
model the relaxation time depends on the sizes 
of clusters of charges on the surfaces of minerals 
rather than on the grain size of particles.

3. Experimental procedures

Laboratory measurements were made on a 
thin disk-shaped hematitic sandstone sample 
with the following dimensions: thickness 6 mm 
and diameter 37 mm. A two electrode technique 
was used with stainless electrodes (of Agilant 
dielectric test fixture 16451B) on the two op-
posite faces of the sample disk. Data were col-
lected in the frequency range from 0.1 Hz up to 
100 KHz using a Hioki 3522- 50 LCR Hitester 
Impedance Analyzer. A voltage of 1V was ap-
plied. The current density in the sample was 
nearly 1×10-3 (microA/cm2) at a frequency of 
10 Hz for the saturated case and nearly 4×10-6 
(microA/cm2) at the same frequency for the dry 
case.

is out of phase with the applied field and has a 
pack up effect in the double layer causing the 
current to be out of phase. Hence the charges 
piled up at the ends of the sphere have an out of 
phase dipole moment. At high frequencies there 
is no build up of a large diffusion cloud outside 
the double layer.

Wong (1979) idealized a disseminated ore 
by a system of electronically conducting metal-
lic spheres randomly dispersed in an electro-
lytic ally conducting host medium. With an 
applied electric field the transport of cations 
and anions in the inter-phase region near the 
metal-electrolyte interface will involve both 
drift and diffusion flux densities. The presence 
of excess or deficit makes ions to accumulate, 
which are loosely held to the surface. The cloud 
of ions surrounding each particle and the diffu-
sion-controlled charge transfer reaction at the 
interface are responsible for inducing a time or 
frequency dependent electric dipole moment on 
each particle.

Mehaute and Crepy (1983) and (Glover et 
al., 1994a; Wong, 1987; Ruffet et al., 1991a, 
1991b)  considered the geometric effects result-
ing from the existence of fractal surfaces. They 
assumed that the internal surfaces of rocks are 
rough and examined how the charge layer is 
built up at the interface. When an electric field 
is applied along the Y-axis normal to the sur-
face, ions have to migrate in this direction. As 
minerals are mainly dielectrics, ions do not pen-
etrate into them and have to migrate along the 
rough surface in the X-direction in order to 
progress further in the Y-direction. The main 
idea is that the exponent a of the Cole and Cole 
(1941) response function is closely related to 
the fractal dimension Df of the surface of the 
solid or, in other words, the distribution of re-
laxation times corresponds to the distribution of 
asperities on a rough surface. For these models, 
the frequency dependent exponent reflects the 
distribution of relaxation times, which in turn is 
connected with ion fluxes passing obstacles of 
various sizes on the rough surface. The experi-
mental data of (Ruffet et al., 1991a, 1991b) has 
been made on the basis of the fractal surface 
model (Mehaute and Crepy, 1983; Wong, 1987). 

The effect of rock/water interaction on the 
dielectric behavior of saturated sandstones has 



805

Relation between electric properties and water saturation for hematitic sandstone with frequency

WS% = (SWW-SWD)/(SWS-SWD)×100

The saturation level by volume is given by

WV% = [(SWW-SWD) × WVD × 100]/(SWW)

where the WS%= Relative water saturation 
percentage by weight, SWW = sample weight 
wet, SWD = sample weight dry, SWS = is the 
sample weight saturated, WV% = Water volume 
percentage, and WVD = wet volume density.

4. Interpretation and discussion of results

The conductivity and dielectric constant in-
crease with the increase of relative saturation 
level. Figures 1 and 2 show the variation of the 
dielectric constant and conductivity, respec-
tively, with frequency at different levels of rela-
tive saturation. If the sample is dry it is sup-
posed that there is no water and the pores are 
completely filled with air. As the saturation in-
creases the adsorbed water forms the first mon-
olayer around the grain surfaces and as the satu-
ration increases gradually the adsorbed water 
tends to make another layer and so on until it 
makes multi-layers of water. The first mono-
layers are supposed to be bound to the surface 
of the grains and the others are supposed to be 
looser. The properties of adsorbed water differ 
significantly from those of the bulk liquid. This 
means that the properties of adsorbed mole-
cules are intermediate between bulk water and 
ice (Chelidze and Guéguen, 1999; Chelidze et 
al., 1999; Knight and Nur, 1987; Knight and 
Endres, 1990; Hoekstra and Doyle, 1971). As 
the water saturation increases the adsorbed wa-
ter coats completely the surfaces of the grains 
and begins to contact with each other forming 
islands of water between grains but those is-
lands are still isolated from each other. The in-
ner layers of water molecules form strong 
bonds with the surface so that they cannot mi-
grate in an electrical field, and the most proba-
ble polarization mechanism is the orientation 
polarization of adsorbed water molecules or 
reversible hopping of H ions along the surface 
(Chelidze and Guéguen, 1999; Chelidze et al., 
1999; Glover et al., 1994a). As saturation in-

The measured parameters are the series and 
parallel capacitance and the series and parallel 
resistance at different frequencies.

Measurement of the electrical properties of 
a material can be made in either the series or 
parallel mode. In the series mode, the complex 
impedance Z is measured, Z = Rs - iXs, where Rs 
is the series resistance (real impedance) and 
Xs = 1/wCs is the reactance, Cs is the series ca-
pacitance. The complex resistivity is 
ρ* = Z × (A/d), where A is the cross-sectional ar-
ea of the sample, d is its thickness. The param-
eters were calculated from the following equa-
tions, ReZ = Rs, ImZ = 1/wCs. For the parallel 
model σ = 1/ρ, ρ = Rp × (A/d). eʹ = Cp/Co, 
Co = (A/d)e0, where w is angular frequency, Rp 
is the parallel resistance, Cp is the parallel ca-
pacitance, e0 is the permittivity of free space 
(8.85 × 10-12 F/m), Gp is the parallel conduct-
ance, and Cp is the parallel capacitance.

The effect of water saturation on electrical 
conductivity is the most important parameter in 
this study. First, the sample was measured in 
the relative atmospheric humidity (~ 65%) in an 
isolated chamber (desiccators). The sample 
weight dry was 14.1 gm. The sample was fully 
saturated by initially evacuating it in a pressure 
vessel, then allowing distilled water to flow 
into the vessel. The saturated weight was 15.45 
gm. Measurements on the fully saturated sam-
ple were made quickly after it was removed 
from the pressure vessel. Subsequent measure-
ments, with the determination of weight, were 
made while the sample was let to dry. The bulk 
volume porosity of the interconnected pore 
volume of the Vp sample was calculated as fol-
lowing:

1) The rock sample is weighed dry (W1); 
2) The sample is then saturated with dis-

tilled water for 24 hours by using a vacuum 
pump; and

3) The completely saturated sample is 
weighed again (W2) and the following equation 
is then applied:

Vp = (W2 - W1)/σf
Where; σf is the fluid density in g/cm3; σf = 1.0 
g/cm3 for the distilled water.

The uncertainty associated with this method 
is of the order of ± 5%. The relative saturation 
levels (in weight) were calculated as



806

M. M. Gomaa

nearly there is only one region. The high fre-
quency region (region 2) has low values of the 
dielectric constant and nearly has no dispersion 
in dielectric constant for low saturations (below 
11%), while there is a slight dispersion for the 
dielectric constant with a very minute slope 
(≈ - 0.1) for high saturations (above 11%).

At low saturations (mainly region 2) the 
physical mechanism of the polarization in ad-
sorbed layers can be either the orientational 
polarization of dipole molecules of water, 
which may be effective at higher frequencies, 
or the transfer of charges (ions in the Helmo-
holtz or diffuse double layer or protons) along 
hydroxilic groups or chains, so-called surface 
charge transfer complexes (Chelidze and 
Guéguen, 1999; Chelidze et al., 1999) or sur-
face polarization in the Stern layer (Schwan et 
al., 1962;   Schwarz, 1962).

The gradual increase in the dielectric con-
stant with the increase of humidity may be at-
tributed to the decrease of the air space dis-
tances between the wet grains that behave as 
capacitors (for low saturations). The capaci-
tance gradually increases as the humidity in-

creases, the electrodes become connected with 
continuous fluid film.

Figure 1 shows the variation of the dielec-
tric constant with frequency at different levels 
of humidity and saturations. Values of the die-
lectric constant at low frequency (0.1 Hz) vary 
from 103 for low saturated hematitic sandstone 
to 2 × 106 for full saturation, while the values at 
high frequency (105 Hz) range from 30 for low 
saturated hematitic sandstone to 200 for full 
saturation (nearly the order of water dielectric 
constant). The dielectric constant dispersion 
(fig. 1) can be generally divided into two re-
gions with power law dependencies on fre-
quency e∝f -a with different exponents (slopes 
on the curves), which are not clearly separated 
at a certain frequency. In the first region at low 
frequencies the slope is steep (≈ - 0.67) for high 
saturation while, for relatively lower satura-
tions it reaches a slope of value ≈ - 0.5 for low 
saturations. That region ends at nearly 2 Hz for 
~ 1% saturations, and extends for higher satura-
tions to 20 KHz (for 50% saturation), while it 
takes the whole frequency range for higher 
saturations. For the fully saturated sample 

Fig. 1. The variation of the dielectric constant with 
frequency at different levels of relative saturations 
(in volume). 4% 0, 8% 0, 11% 0, 14% 0, 18% 0, 25% 
0, 32% 0, 40% 0, 50% 0, 55% 0, 96% 0, 100% 0, 
respectively. There are many symbols that are not 
present.

Fig. 2. The variation of the conductivity with fre-
quency at different levels of relative saturations (in 
volume). 4% 0, 8% 0, 11% 0, 14% 0, 18% 0, 25% 0, 
32% 0, 40% 0, 50% 0, 55% 0, 96% 0, 100% 0, re-
spectively. There are many symbols that are not 
present.



807

Relation between electric properties and water saturation for hematitic sandstone with frequency

(0.1 Hz) vary from 4 × 10-9 Sm-1 for low satu-
rated hematitic sandstone to 3 × 10-5 Sm-1 for 
full saturation, while values for high frequency 
(105 Hz) ranges from 6 × 10-6 Sm-1 for low satu-
rated hematitic sandstone to 2 × 10-3 Sm-1 for 
fully saturation (near the distilled water con-
ductivity).

The first region is characterized by the 
presence of continuous paths of water and he-
matite between the electrodes (above about 
10% saturation), thus causing nearly constant 
conductivity with frequency. Below this criti-
cal saturation (region 2), the continuous paths 
of water between the grains increase with in-
creasing water content, thus the conductivity 
increases.

The low frequency conductivity (fig. 2) and 
dielectric constant change more than five de-
cades with the change of saturation.

It should be noted that these curves are not 
completely identical in behaviour to other 
samples of the same material. Unlike curves 
may be attributed to the variation of the texture 
from sample to another (Parkhomenko, 1967;  
Efros and Shklovskii, 1976;  Knight, 1983;  
Olhoeft, 1985; Sen, 1989; Levitskaya and 
Sternberg, 2000).

The equivalent circuit shown in fig. 3 is as-
sumed to represent the sample in the humid 
case. The conducting grains are completely in-
sulated (blocked) from each other by air. Here, 
Cg and R∞ is the capacitance and resistance of 
the sample at high frequencies, respectively, 
where no space charges accumulate. Ci is the 
interfacial capacitance (frequency independent) 
and Ri is the interfacial resistance (Macdonald, 
1974). The resistance decreases as the frequen-
cy increases, at frequencies lower than the radio 
frequency range, where space charges are ac-
cumulated at interfaces.

When continuous paths are formed (due to 
water and/or hematite) in the sample, the im-
pedance behavior is represented by the equiva-
lent circuit shown in fig. 4. Here RD represents 
a direct frequency-independent conducting path 
between the two electrodes which is effective in 
the low frequency range (Gomaa, 1996). The 
additional resistor RD is equivalent to the 
formed percolation or continuous paths (due to 
water or hematite) in the sample.

creases. When the adsorbed water begins to 
form a continuous path between the electrodes 
additional mechanisms are involved to contribu-
te to increase the dielectric constant, namely the 
gigantic low frequency polarization described 
in the introduction (Chelidze et al., 1999; Che-
lidze, Guéguen, Ruffet, 1999). The continuous 
increase of the dielectric constant with decreas-
ing the frequency may be attributed to the pres-
ence of a distribution of relaxation times due to 
the presence of polarization centers of different 
dimensions on the grains surfaces. 

The frequency separating regions 1 and 2 
increases with increasing the water saturation 
above the critical value (Wilkinson et al., 
1983). Such critical relative water saturation is 
low (about 15%) for water coating grains 
(Dukhin, 1971). 

Charges either diffuse along the humidity 
coating the grains if it is unable to leave the 
surface, or diffuse through the bulk of the 
specimen. The data in the region of saturation is 
a result of the rock/water interaction. Charge 
transport can occur either through the bulk of 
the solid matrix (hematite) or along the grain 
boundaries of solid aggregates (water). When 
soil minerals are exposed to water, exchange-
able ions go into solution, forming an ionic 
halo around the particles. Most of the ionic or 
covalent bonded rock forming minerals such as 
quartz, mica, and feldspars are nonconductors. 
When the surfaces of these minerals come into 
contact with liquid water, electrolytes are 
formed and ionic drift associated with the elec-
trical field causes electrical conduction (Knight 
and Nur, 1987).

In the conductivity curves (fig. 2), two 
nearly corresponding regions may be generally 
found with power law variation of the conduc-
tivity with frequency, which are also clearly 
identified with two regions with different 
slopes. In the first region at low frequencies, for 
low saturations, there is slight dispersion for the 
conductivity. That region ends at nearly 100 Hz 
for saturations below 10 % and extends for 
higher saturations to 20 KHz (for 25 % satura-
tion), while it takes the whole frequency range 
for higher saturations. The second region has 
large slope (~ 0.9) for low saturation (below 10 
%). Values of the conductivity at low frequency 



808

M. M. Gomaa

creases with the increase of the saturation, i.e. 
the conductivity increase (Grant, 1958). Such 
dominance of the real resistivity over the imag-
inary resistivity due to the increase of water 
saturation is representative to the increase in 
continuous conductor (hematite or water) paths 
in the sample.

Figure 9 can be divided into two parts, a 
high frequency part and a low frequency part. 
At higher frequencies the experimental points 

Figures 5, 6, 7, 8 and 9 show the complex 
resistivity plane representation of the sample 
for partial and fully saturated cases. The data 
are presented in 5 figures due to the wide range 
of values on a linear scale. For the low partial 
saturation case nearly a straight line can be 
identified fig. 5. As the saturation increases an 
arc of a depressed semicircle is obtained in figs 
6, 7, 8 and 9, which reflects the effect of the 
resistance RD. The depression of the arc in-

Cg

R
∝

Zi

Ri Ci

Cg

RD

R
∝

Ri

Zi

Ci

Fig. 3. Equivalent circuit that represent the sample 
in the low saturation case (Cg and R∞ are the capaci-
tance and resistance of the sample at the high fre-
quency, respectively, Ci is the interfacial capacitance 
and Ri is the interfacial resistance).

Fig. 4. Equivalent circuit that represents the sample 
in the high and full saturation case (Cg, R∝, Ci and Ri 
is the same as shown in fig. 3). RD represents a fre-
quency-independent conducting path between the 
two electrodes.

Fig. 5. The complex resistivity plane representation 
of the sample for relative saturations 4% ( ), 8% 
( ), 11% ( ), 14% ( ), respectively.

Fig. 6. The complex resistivity plane representation 
of the sample for relative saturations 18% ( ), 25% 
( ), respectively.



809

Relation between electric properties and water saturation for hematitic sandstone with frequency

Fig. 5. The complex resistivity plane representation 
of the sample for relative saturations 4% ( ), 8% ( ), 
11% ( ), 14% ( ), respectively.

tivity or Warburg impedance (Macdonald, 
1974).

The Warburg impedance behavior at the low 
frequencies was attributed to the electrode ef-
fect by (Roberts and Lin, 1997); and also by 
(Knight and Nur, 1987). The latter authors 
stated that the frequency range of electrode ef-
fect extends to higher frequencies with the in-
crease of water.

5. Conclusions

Effects of water saturation on the electrical 
conductivity and dielectric constant of humid, 
partially, and fully saturated hematitic sand-
stone sample is investigated in the frequency 
range from 0.1 Hz to 100 KHz. We change the 
saturation of the sample from normal relative 
humidity (~ 50% RH) to partially and fully sat-
urated condition. Experimental data indicate 
that the electrical conductivity and dielectric 
constant vary strongly with water saturations. A 
transition from nearly normal to gigantic trans-
port is observed at a certain frequency depend-
ing on the water content. The rate of change of 
dielectric constant with saturation is found to 
decrease with frequency.

lie on an arc of a semicircle. The low frequency 
part is a straight line that reflects diffusion 
controlled resistivity. At low frequencies the 
electrode polarization takes place, which is 
humidity or saturation dependent. The straight 
line may represent diffusion controlled resis-

Fig. 7. The complex resistivity plane representation 
of the sample for relative saturations 32% ( ), 40% 
( ), respectively. 

Fig. 8. The complex resistivity plane representation 
of the sample for relative saturations 50% ( ), 55% 
( ), respectively.

Fig. 9. The complex resistivity plane representation 
of the sample for relative saturations 96% ( ), 
100% ( ), respectively.



810

M. M. Gomaa

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The changes in the electrical conductivity and 
dielectric constant due to humidity variation were 
argued to the mobile surface charges at water-
grain interfaces. The simplest surface effect is 
due to surface migration and diffusion of charges 
under an applied field limited by a thin surface 
layer; this can be a conductive film or a closed 
electrical double layer. Film polarization is espe-
cially strong at moderate partial saturations, 
where it can produce strong LF polarization.

Very strong dielectric effects are caused by 
the polarization of «open» electric double layers 
on the solid–liquid interface at large saturations. 
Whereas polarization of bound charges in 
«closed» double layers produces relatively weak 
polarization, akin to that of films, diffusion po-
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between «open» deformed EDL and the adjoin-
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and hence large values of effective dielectric con-
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be applied to heterogeneously charged surfaces.

The anomalous dielectric properties of par-
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predicts that, when the conductive fraction (wa-
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gaps (air) between conductive clusters decreas-
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of the sample and its conductivity.

The results can be explained by electronic 
hopping conduction in the dry case, proton con-
duction in the humid case and low saturations, 
and electrolytic conduction along with protonic 
transport in the fully saturated case.

As a recommendation for this paper more 
controlled saturated samples should be meas-
ured to study clearly the effect of grain size and 
grain shape on the electrical properties of rock 
samples.

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Fig. 8. The complex resistivity plane representation 
of the sample for relative saturations 50% ( ), 55% 
( ), respectively.



811

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(received May 7, 2008;
accepted June 30, 2008)