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Journal ArticleDOI

2.5D resistivity modeling of embankment dams to assess influence from geometry and material properties

Pontus Sjödahl1, Torleif Dahlin1, Bing Zhou2
Lund University1, University of Adelaide2
02 Jun 2006-Geophysics (Society of Exploration Geophysicists)-Vol. 71, Iss: 3, pp 107-114
TL;DR: In this article, the influence from 3D effects created by specific dam geometry and effects of water level fluctuations in the reservoir was evaluated by modeling two rockfill embankment dams with central till cores in the north of Sweden.
Abstract: Repeated resistivity measurement is a potentially powerful method for monitoring development of internal erosion and anomalous seepage in earth embankment dams. This study is part of a project to improve current longterm monitoring routines and data interpretation and increasing the understanding when interpreting existing data. This is accomplished by modeling various occurrences typical of embankment structures using properties from two rockfill embankment dams with central till cores in the north of Sweden. The study evaluates the influence from 3D effects created by specific dam geometry and effects of water level fluctuations in the reservoir. Moreover, a comparison between different layout locations is carried out, and detectability of internal erosion scenarios is estimated through modeling of simulated damage situations. Software was especially developed to model apparent resistivity for geometries and material distributions for embankment dams. The model shows that the 3D effect from the embankment geometry is clearly significant when measuring along dam crests. For dams constructed with a conductive core of fine-grained soil and high-resistive rockfill, the effect becomes greatly enhanced. Also, water level fluctuations have a clear effect on apparent resistivities. Only small differences were found between the investigated arrays. A layout along the top of the crest is optimal for monitoring on existing dams, where intrusive investigations are normally avoided, because it is important to pass the current through the conductive core, which is often the main target of investigation. The investigation technique has proven beneficial for improving monitoring routines and increasing the understanding of results from the ongoing monitoring programs. Although the technique and software are developed for dam modeling, it could be used for estimation of 3D influence on any elongated structure with a 2D cross section.

Summary (3 min read)

Jump to: [INTRODUCTION][Software description][Model geometry, material properties, and damage types][Modeling strategies][3D effects][Reservoir-level fluctuations][Detectability of internal erosion zones][Comparison of different layout locations] and [DISCUSSION AND CONCLUSIONS]

INTRODUCTION

  • Internal erosion is one of the major causes of embankment dam failures.
  • This method has been shown to be effective in revealing information about conditions in the core itself.
  • This means that application of standard 2D techniques on embankment dams with measurement layouts along the crest of the dam cannot be used without cau-tion because of the obvious 3D effects from the dam geometry.
  • The study covered several situations and scenarios essential for interpreting and evaluating data from resistivity measurements on embankment dams.

Software description

  • Software written for 2D resistivity/IP modeling was modified to simulate a dam-monitoring survey by allowing dam geometries in the 2D-model parameterization and a 3D measurement, which means that the current injection and potential pickup may be at any point in the dam.
  • Assumed resistivities must be constant in the electrode-layout direction, i.e., along the dam, and variable in the dam cross section, whereas the electrodes can be placed anywhere in all three dimensions.
  • Such 2.5D modeling is simply accomplished by involving the inverse Fourier transform for an electrode array parallel to the strike direction ͑Dey and Morrison, 1979a, b; Queralt et al., 1991͒.
  • The software uses the finite-element method because this method makes it easier to deal with the dam geometry, compared to the finite-difference method.
  • The authors compared the results with different element sizes and wavenumber sampling schemes.

Model geometry, material properties, and damage types

  • The dam model is a zoned embankment dam with a central till core, surrounding filter zones, and support rockfill ͑Figure 1͒.
  • Because of difficulties in estimating electrical properties of involved materials and lack of appropriate data in literature, some uncertainties are connected to these parameters.
  • For this study, the core resistivity was estimated from existing monitoring data from two Swedish dams ͑Johansson et al., 2000͒ together with laboratory resistivity measurements of similar till samples ͑Bergström, 1998͒ -even though an unsatisfying variation was found in this data.
  • Damaged zones often have this kind of extended shape because the dam is constructed in layers.
  • A resistivity increase of five times in the core was assumed because of internal erosion.

Modeling strategies

  • To evaluate responses from different electrode arrays, four arrays were selected for all modeling situations.
  • An electrode spacing of 5 m was selected for the dam model because that gives a reasonable relation between electrode spacing and dam height similar to what could be expected in an actual in situ situation.
  • All combinations, including a-spacings from one to seven ͑multiples of five͒ and n-factors ͑one to six͒, were used for the calculations.
  • Of the four examined arrays, dipole-dipole is by its nature most different from the others, and in some situations, it gave responses that were different than the others.
  • Only when examining special cases, such as cylindrical damages or elongated damage zones with lim-.

3D effects

  • The 3D effects and their dependency on material parameters were examined for a dam with the model cross section described in Figure 1 .
  • The effects were estimated by comparing the responses from two models: a 2.5D model and a 1D model with the properties of the model midsection, i.e., the section with the electrode layout extended to horizontal layers.
  • Sample results for the dipole-dipole and the Schlumberger arrays are shown in Figure 2 .
  • Next, the dependency of input-material parameters was similarly evaluated using a model with constant resistivity for the whole dam cross section, including the reservoir water.
  • It is obvious that most of the huge 3D effect arises from the contrast between the relatively conductive core and the high resistivity of the main part of the dam cross section.

Reservoir-level fluctuations

  • The effect of lowering the reservoir was examined, using the dam model in Figure 1 .
  • 3D effects estimated as relation between 1D and 2.5D models with assumed material properties for the modeled cross section and reservoir.
  • For both arrays, a-spacing is the spacing between potential electrodes, and n-factor is the shortest distance between potential and current electrode divided by the a-spacing.
  • The calculations were made once for each depth.
  • For the large lowering of the reservoir, the same effect was estimated to be moving toward approximately 40% ͑1.40 times͒ for the largest electrode distances.

Detectability of internal erosion zones

  • When internal erosion occurs, the material properties of the eroded zone will change as porosity increases and fines are washed away.
  • A permanent or possibly semipermanent change ͑because it may heal by itself͒ in the resistivity characteristics of the dam core will occur.
  • To estimate the imaging potential of the damages, standard 1D, multilayer, smooth inversion ͑Auken et al., 2004͒ was carried out on the forward model responses.
  • The anomaly effect is enhanced through inversion, but effects from the dam geometry cause the damage to localize at a shallower level than the real case ͑Figure 9͒.
  • It is not likely that the damages would be detected by a single survey, but with repeated measurements the possibilities would be fair.

Comparison of different layout locations

  • Modeling of different layout placements is helpful for interpreting data from Swedish dam monitoring, especially at the Hällby Dam, where layouts are not only placed along the crest but also on a line along the upstream and the downstream side ͑Johansson et al., 2000͒.
  • All of them are placed directly beneath the surface of the dam.
  • For the layouts along the upstream toe and the mid-upstream slope, the upstream electrodes are placed below the water table.
  • The calculated-anomaly effects are less than 1% ͑Ͻ1.01 times͒ for all different placements of the layouts, re- gardless of the damage location.
  • Obviously, the channeling effect that concentrates current flow within the conductive dam core is an important factor.

DISCUSSION AND CONCLUSIONS

  • Resistivity measurements on embankment dam geometries are influenced by many factors, such as effects caused by the geometry and variation in material properties across the dam cross section, impact of water-level changes, and electrode-layout location.
  • The influence is similar for all of the examined arrays, ranging from three to seven times the value of the standard 1D model for the geometry and material properties assumed.
  • Resistivities measured along the dam crest were shown to be significantly influenced by fluctuations in the reservoir level.
  • It is unlikely that such damages could be detected by a single resistivity survey using surface electrodes.
  • Also note that all damage types were shaped as extended layers and that the results may not be fully applicable, for instance, to a cylindrically shaped damage and other damage zones with limited extent along the dam.

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2.5D resistivity modeling of embankment dams to assess influence from geometry and
material properties
Sjödahl, Pontus; Dahlin, Torleif; Zhou, Bing
Published in:
Geophysics
DOI:
10.1190/1.2198217
2006
Link to publication
Citation for published version (APA):
Sjödahl, P., Dahlin, T., & Zhou, B. (2006). 2.5D resistivity modeling of embankment dams to assess influence
from geometry and material properties.
Geophysics
,
71
(3), G107-G114. https://doi.org/10.1190/1.2198217
Total number of authors:
3
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2.5D resistivity modeling of embankment dams to assess
influence from geometry and material properties
Pontus Sjödahl
1
, Torleif Dahlin
1
, and Bing Zhou
2
ABSTRACT
Repeated resistivity measurement is a potentially powerful
method for monitoring development of internal erosion and
anomalous seepage in earth embankment dams. This study is
part of a project to improve current longterm monitoring rou-
tines and data interpretation and increasing the understanding
when interpreting existing data. This is accomplished by mod-
eling various occurrences typical of embankment structures us-
ing properties from two rockfill embankment dams with central
till cores in the north of Sweden. The study evaluates the influ-
ence from 3D effects created by specific dam geometry and ef-
fects of water level fluctuations in the reservoir. Moreover, a
comparison between different layout locations is carried out,
and detectability of internal erosion scenarios is estimated
through modeling of simulated damage situations. Software
was especially developed to model apparent resistivity for ge-
ometries and material distributions for embankment dams. The
model shows that the 3D effect from the embankment geometry
is clearly significant when measuring along dam crests. For
dams constructed with a conductive core of fine-grained soil
and high-resistive rockfill, the effect becomes greatly enhanced.
Also, water level fluctuations have a clear effect on apparent re-
sistivities. Only small differences were found between the in-
vestigated arrays. A layout along the top of the crest is optimal
for monitoring on existing dams, where intrusive investigations
are normally avoided, because it is important to pass the current
through the conductive core, which is often the main target of
investigation. The investigation technique has proven beneficial
for improving monitoring routines and increasing the under-
standing of results from the ongoing monitoring programs. Al-
though the technique and software are developed for dam mod-
eling, it could be used for estimation of 3D influence on any
elongated structure with a 2D cross section.
INTRODUCTION
Internal erosion is one of the major causes of embankment dam
failures. Monitoring systems can significantly improve the safety
of such dams. However, to detect erosion early, monitoring sys-
tems must be highly sensitive and, at the same time, sufficiently
cover the embankment area. In addition, it should be possible to in-
stall such monitoring systems in existing dams, and these systems
should be capable of identifying small seepage changes, as well as
leakage. Experience from research and field installations carried
out in Sweden since 1993 indicates that monitoring systems based
on resistivity measurements may be able to meet this need Johans-
son and Dahlin, 1996; Johansson and Dahlin, 1998; Johansson et
al. 2000. In addition, using a resistivity monitoring technique is
essentially nondestructive. This is particularly important when
working with embankment dams, where drilling and other pen-
etrating investigations are normally avoided.
An electrode layout along the top of the dam core is the most
practical and favorable method of installing resistivity monitoring
systems on existing dams. This will be shown later in the paper.
This method has been shown to be effective in revealing informa-
tion about conditions in the core itself. In addition, good electrode
grounding conditions can be provided in the fine-grained environ-
ment commonly found in the dam core Dahlin et al., 2001. Stan-
dard 2D-inversion schemes are a common technique for processing
data from resistivity profiling Smith and Vozoff, 1984; Tripp et al.,
1984; Li and Oldenburg, 1992; Loke and Barker, 1995; LaBrecque
et al., 1996.
When doing 2D inversion, it is assumed that the properties of
the ground are constant in the third dimension, i.e., the direc-
tion perpendicular to the electrode layout. Deviations from this are
commonly referred to as 3D effects. This means that application of
standard 2D techniques on embankment dams with measurement
layouts along the crest of the dam cannot be used without cau-
Manuscript received by the Editor March 25, 2004; revised manuscript received August 13, 2005; published online May 24, 2006.
1
Lund University, Engineering Geology, Box 118, 221 00 Lund, Sweden. E-mail: pontus.sjodahl@tg.lth.se; torleif.dahlin@tg.lth.se.
2
University of Adelaide, Department of Physics, School of Chemistry & Physics, South Australia 5005, Australis. E-mail: bing.zhou@adelaide.edu.au.
© 2006 Society of Exploration Geophysicists. All rights reserved.
GEOPHYSICS, VOL. 71, NO. 3 MAY-JUNE 2006; P. G107–G114, 9 FIGS., 3 TABLES.
10.1190/1.2198217
G107
tion because of the obvious 3D effects from the dam geometry. It is
possible to use 3D inversion techniques Park and Van, 1991;
Sasaki, 1994; Zhang et al., 1995; Loke and Barker, 1996. How-
ever, they still may not be convenient for repeated measurements,
mainly because of limitations in computational resources and be-
cause data sets are 2D if only measured along the crest. Therefore,
a reasonable approach is to use common 2D techniques and then
estimate the distortions and errors that are induced in the process.
Heretofore, the terms 3D effect refer to the errors received when
measuring along an embankment, assuming standard 2D condi-
tions. The most obvious effect is the embankment topography;
however, the most significant effect might come from the variation
in electrical properties of the construction materials in the zoned
embankment dam.
The aim of this study was to improve current, longterm monitor-
ing routines on two embankment dams in the north of Sweden. The
study covered several situations and scenarios essential for inter-
preting and evaluating data from resistivity measurements on em-
bankment dams. Investigations of these different situations were
carried out through numerical calculations. The influence of the
specific dam geometry and zoned construction materials was in-
vestigated via dedicated, 2.5D software. Effects of reservoir water
level and natural, seasonal resistivity variation in the water were
examined as well. Moreover, a comparison was carried out to de-
termine the differences in the efficiency in detecting seepage zones
for four different electrode arrays.
Much work has been done on resistivity forward modeling in 2D
and 3D using the finite-difference method Mufti, 1976; Dey and
Morrison, 1979a, b; Fox et al., 1980 and the finite-element method
Pridmore et al., 1981; Queralt et al., 1991; Sasaki, 1994; Zhou and
Greenhalgh, 2001. Investigative resistivity surveys on embank-
ments to detect structural defects or anomalous seepage are fairly
widespread Abuzeid, 1994; Engelbert et al., 1997; Titov et al.,
2000; Van Tuyen et al., 2000; Buselli and Lu, 2001; Panthulu et al.,
2001; Voronkov et al., 2004. However, modeling studies to find
out more about typical effects from dam geometries is less com-
mon.
If 3D modeling were to be used for our study, large and compu-
tationally heavy models would have been needed to assess the 3D
effects without influence from the finite length of the model.
Therefore, software capable of handling typical dam geometries
was developed for the numerical calculations. This software is a
useful tool for optimizing the monitoring program design and to
improve the interpretation of collected data. It uses forward model-
ing to find the apparent resistivity distribution in earth embank-
ment dams for a given geometry and measurement layout. Addi-
tionally, it is general and may be utilized for many types of
elongated structures, as long as they can be described with an arbi-
trary although constant geometry in the plane perpendicular to
the electrode layout direction.
NUMERICAL MODELING
Software description
Software written for 2D resistivity/IP modeling was modified to
simulate a dam-monitoring survey by allowing dam geometries in
the 2D-model parameterization and a 3D measurement, which
means that the current injection and potential pickup may be at any
point in the dam. The original 2D software was written for 2D-
resistivity tomography and used the common practical situation,
where resistivity tomographic-imaging surveying is conducted in
the plane perpendicular to the strike direction, allowing arbitrary
variation of resistivity in that plane.
More precisely, the modification of the software was done in two
parts. The first considered adjustments of the elements to fit best
the outline and the inner structure of the dam Figure 1, which was
done by applying the finite-element method Zhou, 1998; Zhou
and Greenhalgh, 1999. The second part regarded the calculation
of the potentials parallel to the strike direction. This was accom-
plished by performing the inverse, Fourier-cosine transform with
nonzero y-coordinate of the potential position, according to the
method described by Queralt et al. 1991.
Hence, the modified software is applicable for modeling of the
resistivity structure with surface profile or crosshole survey. How-
ever, because the current electrodes and the potential measure-
ments must be modeled in 3D for the dam survey, we refer to it as
2.5D modeling. Assumed resistivities must be constant in the
electrode-layout direction, i.e., along the dam, and variable in the
dam cross section, whereas the electrodes can be placed anywhere
in all three dimensions. Such 2.5D modeling is simply accom-
plished by involving the inverse Fourier transform for an electrode
array parallel to the strike direction Dey and Morrison, 1979a, b;
Queralt et al., 1991. The approach is more efficient than a full 3D
model, and for an elongated embankment with constant cross sec-
tion, the drawbacks are moderate. Hence, it is an efficient tool for
assessing 3D effects on 1D and 2D resistivity surveying.
The software uses the finite-element method because this
method makes it easier to deal with the dam geometry, compared to
the finite-difference method. It is valid for calculating potential,
apparent resistivity, or IP responses for a model with arbitrary re-
sistivity distribution in the plane perpendicular to the electrode-
layout direction and for any electrode configurations, e.g., surface,
crosshole, or mise-a-la-masse, off-line and in-line measurements
with pole-pole, pole-dipole, dipole-dipole, Schlumberger, and
mixed arrays Zhou and Greenhalgh, 1999.
The accuracy of 2.5D modeling has been checked by comparing
it with some known analytic solutions Zhou, 1998. It has been
shown that the modeling accuracy mainly depends on the element
size, electrode spacings that give different ranges of the wave-
number, and the wavenumber sampling for accurate inverse-
Fourier transform. To obtain satisfactory results for the dam mod-
eling, we determined the accuracy-control parameters by applying
the dam geometry and the electrode layouts employed in the fol-
lowing simulations. We compared the results with different ele-
ment sizes and wavenumber sampling schemes. We found that the
results showed relative errors less than 1%, using element sizes of
about 1 m and 40 wavenumber sampling points.
Model geometry, material properties,
and damage types
The dam model is a zoned embankment dam with a central till
core, surrounding filter zones, and support rockfill Figure 1. This
is the most common design of large Swedish embankment dams.
Geometry and design values are given in Table 1. The electrode
layout is buried 1 m into the top of the core at the midpoint of the
cross section.
Because of difficulties in estimating electrical properties of in-
volved materials and lack of appropriate data in literature, some
uncertainties are connected to these parameters. Here, the rockfill
G108 Sjödahl et al.
was treated as an insulated matrix with all electrical conduction
concentrated to the pore spaces. Thus, Archie’s law was used using
porosity estimates. However, the porosity estimates are to some
extent uncertain in themselves. Regarding the core, the matrix can
no longer be considered an insulator, and other material models
must be used. For this study, the core resistivity was estimated
from existing monitoring data from two Swedish dams Johansson
et al., 2000 together with laboratory resistivity measurements of
similar till samples Bergström, 1998 even though an unsatis-
fying variation was found in this data.
The resistivity of the filter zones has less influence on the mod-
eling results and was assumed to be somewhere between the resis-
tivity of the core and the rockfill. The resistivity of the reservoir
water was taken from monitoring data Johansson et al., 2000.
Electrical material properties are listed in Table 2. In an interna-
tional perspective, these values are quite high, mainly because of
the high resistivity of the water. Assuming a porosity of approxi-
mately 25% may lead to resistivities of several thousand ohmme-
ters in the saturated rockfill. Keep in mind that the main factor in-
fluencing the results is the relative differences in resistivities for
the involved materials.
The simulated damages were studied for two different depths
Table 3. They could be physically interpreted as damaged layers,
possibly resulting from less compaction at initial construction and
possibly worsened as a consequence of regional piping causing a
transport of fines from the core to the filter and fill. The damages
were extended along the full length of the dam. Damaged zones of-
ten have this kind of extended shape because the dam is con-
structed in layers. Even though an extension along the full length
of the dam is not realistic, simulating these kinds of scenarios still
yields useful information. Furthermore, because of software re-
strictions, the modeled-dam cross section must be identical along
the whole length of the dam. Therefore, for example, it was impos-
sible to simulate a concentrated, cylindrical, damage zone through
the dam.
A resistivity increase of five times in the core was assumed be-
cause of internal erosion. Experiments on similar tills have shown
that resistivity can increase up to 10 times because of removal of
fines under water-saturated conditions Bergström, 1998. How-
ever, this should be handled with care because internal erosion in-
creases porosity, affecting the resistivity in the opposite direction.
The resistivity of the filter and fill was assumed not to change be-
cause of the simulated damages.
Modeling strategies
To evaluate responses from different electrode arrays, four ar-
rays were selected for all modeling situations. The dipole-dipole,
pole-dipole, Wenner-Schlumberger, and gradient arrays were cho-
sen because they have shown robust imaging quality in prior mod-
eling studies Dahlin and Zhou, 2004. An electrode spacing of
5 m was selected for the dam model because that gives a reason-
able relation between electrode spacing and dam height similar to
what could be expected in an actual in situ situation. All combina-
tions, including a-spacings from one to seven multiples of five
and n-factors one to six, were used for the calculations. The total
was 42 individual measurements for each array. Generally, the four
different arrays demonstrated similar responses for the different
modeled situations. This was particularly true for the pole-dipole,
Wenner-Schlumberger, and gradient, which are all geometrically
associated. Of the four examined arrays, dipole-dipole is by its na-
ture most different from the others, and in some situations, it gave
responses that were different than the others. Thus, only results
from dipole-dipole and Wenner-Schlumberger arrays will be pre-
sented.
Certainly, when investigating constant cross sections, i.e., no lat-
eral changes, the differences in the design of the arrays will not
show up fully in the results. Only when examining special cases,
such as cylindrical damages or elongated damage zones with lim-
Figure 1. The modeled cross section geometry. A zoned, rockfill
embankment dam with a central till core and surrounding filter
zones. Electrode layouts and damage zones that are used in the
study are marked out.
Table 1. Dam geometry design parameters (see also
Figure 1).
Dam height 60 m
Crest width 8 m
Upstream and downstream slopes 0.55:1
Distance: Top of core crest 3 m
Distance: Max reservoir level crest 6 m
Core width at top/bottom 4 m/20 m
Filter thickness outside core/top core 4 m/1 m
Table 2. Electrical material properties.
Material Resistivity
m
Core 300
Filter 2000
Upstream fill 4000
Downstream fill 20 000
Reservoir water 550
Damaged core 1500
Table 3. Damage types.
Damage type
Thickness of
damaged layer
Depth from crest to
center of damaged layer
Type 1: Thin seepage
zone layer
2 m 20 m
Type 2: Thin seepage
zone layer
2 m 50 m
2.5D Resistivity modeling of embankment dams G109
ited length, can a full verification of the performance of the differ-
ent arrays be obtained.
RESULTS
3D effects
The 3D effects and their dependency on material parameters
were examined for a dam with the model cross section described in
Figure 1. The effects were estimated by comparing the responses
from two models: a 2.5D model and a 1D model with the proper-
ties of the model midsection, i.e., the section with the electrode
layout extended to horizontal layers. The 2.5D model generated
three to seven times higher responses than the 1D model. Sam-
ple results for the dipole-dipole and the Schlumberger arrays are
shown in Figure 2.
Next, the dependency of input-material parameters was simi-
larly evaluated using a model with constant resistivity for the
whole dam cross section, including the reservoir water. The result-
ing effect, caused by the topography for a homogeneous embank-
ment, gave an increase in resistivity of about 30% 1.30 times for
the 2.5D model Figure 3. It is obvious that most of the huge 3D
effect arises from the contrast between the relatively conductive
core and the high resistivity of the main part of the dam cross sec-
tion. Most of the current flow is concentrated in the core that geo-
metrically constitutes a rather thin sheet Figure 4.
Reservoir-level fluctuations
The effect of lowering the reservoir was examined, using the
dam model in Figure 1. This was done because the reservoir water
Figure 2. 3D effects estimated as relation between 1D and 2.5D models with assumed material properties for the modeled cross section and
reservoir. a Dipole-dipole and b Wenner-Schlumberger arrays with a-spacing of 5–35 m in steps of 5 m and n-factors 1-6. For both ar-
rays, a-spacing is the spacing between potential electrodes, and n-factor is the shortest distance between potential and current electrode di-
vided by the a-spacing.
Figure 3. Purely geometrical 3D effects estimated as relation between 1D and 2.5D models with equal material properties in the whole cross
section and reservoir. a Dipole-dipole and b Wenner-Schlumberger arrays with a-spacing of 5–35 m in steps of 5 m and n-factors 1-6.
G110 Sjödahl et al.
Citations
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Abstract: The research aims to assess the geothermal potential and provide a better understanding of the geology and geophysics of the area. The study utilizes various methods, including geological mapping, geochemical analysis, and magnetic and electromagnetic data analysis, to gain insights into the subsurface structures and characteristics of the geothermal system. The study area can be divided into three geomorphological units: Alluvial Plain Unit, Near Plains Unit, and Isolated Hill Unit. The study area exhibits a stratigraphy consisting of three primary units: Talumopatu granite units, Talumopatu sandstone units, and alluvial deposit units. The subsurface lithologies of the Talumopatu manifestation area were analyzed using the Wenner – Alpha configuration ERT method, revealing two distinct lithologies. The first lithology consists of sandstones with a resistivity value ranging from 4.2 to 39.0 Ωm and a thickness of 1.25 to 12.4 m, which act as a permeable layer capable of transmitting water. The second lithology is granite with a resistivity value ranging from 118 to 360 Ωm and a thickness of 3.75 to 15.9 m. This information provides valuable insights into the subsurface characteristics of the area, including the presence of permeable layers and the geological composition of the lithologies
Feasibility studies on the water level for dam leakage detection using the direct current resistivity method: tha thung na dam case

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Sarunya Chomchaiya, Chatchai Vachiratienchai, Weerachai Siripunvaraporn
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TL;DR: In this paper, a 3D resistivity model of one section of the Tha Thung Na dam was constructed by gathering geometry and statistical information of the dam and constructed the 3-D resistivities model of the 3D model.
Abstract: The direct current resistivity (DCR) method is used in monitoring and detecting the internal erosion inside the dam’s core. Although geometry of the dam is perfectly 3-D, its geometry only allows the measurement along the crest of the dam (2-D profile). Therefore, the 3-D effects such as slopes of dam and water levels will play significant roles for the results of the 2-D measurement which is our first aim here but will only mention just the water level as it can change with time. Second aim is to probe whether the 2-D measurement can effectively image the damage zone at the core of the dam, if really occur. We started by gathering geometry and statistical information of the Tha Thung Na dam and constructed the 3-D resistivity model of one section of the Tha Thung Na dam. About 48 electrodes (4 meter spacing) are placed along the crest. The 3-D numerical simulation is performed to generate the apparent resistivity before inverting them with the 2-D inversion to generate the subsurface resistivity image. Our studies confirm that the water can greatly influence the 2-D measurement. The 3-D effects should be taken into account when performing the interpretation. In addition, when the damage zones are added into the synthetic model, the DCR technique can image them with some difficulty if they are at great depth. Absolute resistivity difference between the inverted model of the case with leak and that of the healthy dam can help enhance the damage zone. Although no damage have been reported in the Tha Thung Na dam before, the aim of this study is therefore not to cause public panic but used this study as a prototype for any dams in Thailand.
Resistivity monitoring for the detection of leakage zones in earth fill dams

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I. Ky Cho, I. Soo Ha, K. Seog Kim, H. Yoon Ahn, S. Lee, H. Jin Kang, R. Supper 
04 Jul 2011
Abstract: We applied the resistivity monitoring at an embankment dam to effectively identify the leakage zones or their expansion with time. We first analyzed the three-dimensional (3D) effects caused by 3D dam structure through 3D finite element modeling. Through numerical tests, we demonstrated the effectiveness of time-lapse inversion for the detection of leakage zone at embankment dams. Applying the resistivity monitoring system devised for dam surveillance to a test dam site, resistivity monitoring data were acquired. Noise characteristics of collected resistivity data were analyzed and a processing procedure was proposed to establish a proper reference model for the time-lapse inversion of future monitoring data. Introduction More than 16 percent of 18,000 reservoir dams in Korea are reported to have leakage problems and need to be repaired. Recently, resistivity monitoring has been applied to wide range of engineering and environmental problems with the help of automatic/rapid data acquisition, data communication and effective interpretation software. Resistivity survey and long term monitoring at an embankment dam can provide helpful information about leakage zones. Resistivity monitoring is based on the fact that a change in the porosity leads to the changes in water content and fine particles, which alter the electrical resistivity. At every embankment dam, internal erosion always occurs as time passes. The internal erosion generally develops into piping over a long time by backward erosion and concentrated leak, and finally leads to dam failure. Thus internal erosion and piping are major cause of embankment dam failure. Internal erosion initially results in an increased porosity due to loss of fine particles in the core. Resistivity is known to be very sensitive to the changes in porosity in embankment dams. Thus resistivity monitoring is a reasonable method to find out the leakage zone. However, resistivity is strongly influenced by seasonal variation of temperature, TDS of reservoir water and water level (SJÖDAHL et al., 2008). Also, various noises prevent accurate measurement of resistivity. These make it very hard to accurately interpret resistivity monitoring data. In the resistivity monitoring, significant challenges still remain in data acquisition system, noise suppression and time-lapse inversion for more detailed and quantitative interpretation. Here, we will present various problems occurring in the resistivity monitoring for the detection of leakage zones at embankment dams. Berichte Geol. B.-A., 93, ISSN 1017‐8880 – Applications in Engineering

Cites background from "2.5D resistivity modeling of embank..."

  • ...Topography also does not fulfill the 2D condition and 3D effects caused by the 3D dam structure distort apparent resistivity data (SJÖDAHL et al., 2006; CHO and YEOM, 2007)....

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  • ...the 3D dam structure distort apparent resistivity data (SJÖDAHL et al., 2006; CHO and YEOM, 2007)....

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Journal ArticleDOI
Resistivity imaging of river embankments: 3D effects due to varying water levels in tidal rivers

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John H. Ball, Jonathan Chambers, G. Wilkinson, Andrew Binley
22 Sep 2022-Near Surface Geophysics
TL;DR: In this paper , the authors quantify potential 3D effects on the electrical resistivity tomography (ERT) data collected from Hadleigh Marsh, UK, and show that the 3D effect in a tidal environment occurs when surveys are undertaken at high water levels and at distances less than 4.5 m from the electrode array with 1 m spacing.
Abstract: Electrical resistivity tomography (ERT) has seen increased use in the monitoring the condition of river embankments, due to its spatial subsurface coverage, sensitivity to changes in internal states, such as moisture content, and ability to identify seepage and other erosional process with time-lapse ERT. Two-dimensional ERT surveys are commonly used due to time and site constraints, but they are often sensitive to features of anomalous resistivity proximal to the survey line, which can distort the resultant inversion as a three-dimensional (3D) effect. In a tidal embankment, these 3D effects may result from changing water levels and river water salinities. ERT monitoring data at Hadleigh Marsh, UK, showed potential evidence of 3D effects from local water bodies. Synthetic modelling was used to quantify potential 3D effects on tidal embankments. The modelling shows that a 3D effect in a tidal environment occurs (for the geometries studied) when surveys are undertaken at high water levels and at distances less than 4.5 m from the electrode array with 1 m spacing. The 3D effect in the modelling is enhanced in brackish waters, which are common in tidal environments, and with larger electrode spacing. Different geologies, river water compositions, and proximities to the model parameters are expected to induce a varied 3D effect on the ERT data in terms of magnitude, and these should be considered when surveying to minimize artefacts in the data. This research highlights the importance of appropriate geoelectrical measurement design for tidal embankment characterization, particularly with proximal and saline water bodies.
Patent
Création de maillages de réservoirs par raffinement étendu anisotrope géométriquement adaptatif de polyèdres

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Michael Loyd Brewer, Steven Bryan Ward, Gerrick O. Bivins
12 Nov 2014
TL;DR: In this article, a raffine de maniere anisotrope des cellules du maillage correspondant aux autres fractures is used to model the fractures.
Abstract: L'invention concerne des systemes et procedes de creation de maillages de reservoirs, utilisant un raffinement etendu anisotrope geometriquement adaptatif de polyedres. Dans un exemple, un procede selon l'invention comprend l'etape consistant a identifier, d'apres une specification recue de reservoir: un ensemble de fractures comprenant des fractures autorisant une dimension 2,5 (2,5D) et d'autres fractures. Le procede comprend en outre l'etape consistant a generer un modele intermediaire de reservoir comprenant un maillage par extrusion qui modelise les fractures autorisant le 2,5D dans un espace tridimensionnel (3D). En reaction a une determination selon laquelle des cellules du maillage doivent etre raffinees dans une direction au sein de l'espace 3D, le procede raffine de maniere anisotrope des cellules du maillage correspondant aux autres fractures. Le procede comprend egalement les etapes consistant a resoudre un reseau de fractures au sein du modele intermediaire de reservoir en utilisant les cellules raffinees, puis a generer un modele de terre du reservoir en utilisant le reseau de fractures.
References
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Journal ArticleDOI
A numerical comparison of 2D resistivity imaging with 10 electrode arrays

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Torleif Dahlin1, Bing Zhou2
Lund University1, University of Adelaide2
01 Sep 2004-Geophysical Prospecting
TL;DR: In this article, numerical simulations are used to compare the resolution and efficiency of 2D resistivity imaging surveys for 10 electrode arrays, including pole-pole (PP), pole-dipole (PD), half-Wenner (HW), Wenner-α (WN), Schlumberger (SC), dipole-dipsole (DD), WenNER-β (WB), γ -array (GM), multiple or moving gradient array (GD) and midpoint-potential-referred measurement (MPR) arrays.
Abstract: Numerical simulations are used to compare the resolution and efficiency of 2D resistivity imaging surveys for 10 electrode arrays. The arrays analysed include polepole (PP), pole-dipole (PD), half-Wenner (HW), Wenner-α (WN), Schlumberger (SC), dipole-dipole (DD), Wenner-β (WB), γ -array (GM), multiple or moving gradient array (GD) and midpoint-potential-referred measurement (MPR) arrays. Five synthetic geological models, simulating a buried channel, a narrow conductive dike, a narrow resistive dike, dipping blocks and covered waste ponds, were used to examine the surveying efficiency (anomaly effects, signal-to-noise ratios) and the imaging capabilities of these arrays. The responses to variations in the data density and noise sensitivities of these electrode configurations were also investigated using robust (L1-norm) inversion and smoothness-constrained least-squares (L2-norm) inversion for the five synthetic models. The results show the following. (i) GM and WN are less contaminated by noise than the other electrode arrays. (ii) The relative anomaly effects for the different arrays vary with the geological models. However, the relatively high anomaly effects of PP, GM and WB surveys do not always give a high-resolution image. PD, DD and GD can yield better resolution images than GM, PP, WN and WB, although they are more susceptible to noise contamination. SC is also a strong candidate but is expected to give more edge effects. (iii) The imaging quality of these arrays is relatively robust with respect to reductions in the data density of a multi-electrode layout within the tested ranges. (iv) The robust inversion generally gives better imaging results than the L2-norm inversion, especially with noisy data, except for the dipping block structure presented here. (v) GD and MPR are well suited to multichannel surveying and GD may produce images that are comparable to those obtained with DD and PD. Accordingly, the GD, PD, DD and SC arrays are strongly recommended for 2D resistivity imaging, where the final choice will be determined by the expected geology, the purpose of the survey and logistical considerations.

731 citations

Journal ArticleDOI
Practical techniques for 3D resistivity surveys and data inversion1

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M.H. Loke1, R. D. Barker2
Universiti Sains Malaysia1, University of Birmingham2
01 May 1996-Geophysical Prospecting
TL;DR: In this article, a smoothing-constrained least-squares inversion method is used for the data interpretation and the computing time required by this technique is greatly reduced by using a homogeneous half-space as the starting model so that the Jacobian matrix of partial derivatives can be calculated analytically.
Abstract: Techniques to reduce the time needed to carry out 3D resistivity surveys with a moderate number (25 to 100) of electrodes and the computing time required to interpret the data have been developed. The electrodes in a 3D survey are normally arranged in a square grid and the pole-pole array is used to make the potential measurements. The number of measurements required can be reduced to about one-third of the maximum possible number without seriously degrading the resolution of the resulting inversion model by making measurements along the horizontal, vertical and 45° diagonal rows of electrodes passing through the current electrode. The smoothness-constrained least-squares inversion method is used for the data interpretation. The computing time required by this technique can be greatly reduced by using a homogeneous half-space as the starting model so that the Jacobian matrix of partial derivatives can be calculated analytically. A quasi-Newton updating method is then used to estimate the partial derivatives for subsequent iterations. This inversion technique has been tested on synthetic and field data where a satisfactory model is obtained using a modest amount of computer time. On an 80486DX2/66 microcomputer, it takes about 20 minutes to invert the data from a 7 by 7 electrode survey grid. using the techniques described below, 3D resistivity surveys and data inversion can be carried out using commercially available field equipment and an inexpensive microcomputer.

678 citations

"2.5D resistivity modeling of embank..." refers methods in this paper

  • ...It is ossible to use 3D inversion techniques Park and Van, 1991; asaki, 1994; Zhang et al., 1995; Loke and Barker, 1996 ....

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Journal ArticleDOI
Least-squares deconvolution of apparent resistivity pseudosections

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M. H. Loke1, R. D. Barker1
University of Birmingham1
01 Dec 1995-Geophysics
TL;DR: In this article, a smoothness-constrained least square method is used to produce a 2D subsurface model free of distortions in the apparent resistivity pseudosection caused by the electrode array geometry used.
Abstract: A fast technique for the inversion of data from resistivity tomography surveys has been developed. This technique is based on the smoothness-constrained, least-squares method, and it produces a 2-D subsurface model that is free of distortions in the apparent resistivity pseudosection caused by the electrode array geometry used. A homogeneous earth model is used as the starting model for which the apparent resistivity partial derivative values can be calculated analytically. Tests with a variety of models and data from field surveys show that this technique is insensitive to random noise, provided a sufficiently large damping factor is used, and that it can resolve structures that cause overlapping anomalies in the pseudosection. On a 33 MHz 80486DX microcomputer, it takes about 5 s to process a single data set.

568 citations

"2.5D resistivity modeling of embank..." refers methods in this paper

  • ...…Geophysics, 61, 538–548. i, Y. G., and D. W. Oldenburg, 1992, Approximate inverse mapping in DC resistivity problems: Geophysical Journal International, 109, 343–362. oke, M. H., and R. D. Barker, 1995, Least-squares deconvolution of ap- parent resistivity pseudosections, Geophysics, 60, 1682–1690....

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  • ...Stanard 2D-inversion schemes are a common technique for processing ata from resistivity profiling Smith and Vozoff, 1984; Tripp et al., 984; Li and Oldenburg, 1992; Loke and Barker, 1995; LaBrecque t al., 1996 ....

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Journal ArticleDOI
The effects of noise on Occam's inversion of resistivity tomography data

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Douglas LaBrecque1, Michela Miletto1, William Daily1, Aberlardo Ramirez1, Earle Owen1 
University of Arizona1
01 Apr 1996-Geophysics
TL;DR: In this paper, an Occam's inversion algorithm for crosshole resistivity data that uses a finite-element method forward solution is discussed, where the earth is discretized into a series of parameter blocks, each containing one or more elements.
Abstract: An Occam's inversion algorithm for crosshole resistivity data that uses a finite-element method forward solution is discussed. For the inverse algorithm, the earth is discretized into a series of parameter blocks, each containing one or more elements. The Occam's inversion finds the smoothest 2-D model for which the Chi-squared statistic equals an a priori value. Synthetic model data are used to show the effects of noise and noise estimates on the resulting 2-D resistivity images. Resolution of the images decreases with increasing noise. The reconstructions are underdetermined so that at low noise levels the images converge to an asymptotic image, not the true geoelectrical section. If the estimated standard deviation is too low, the algorithm cannot achieve an adequate data fit, the resulting image becomes rough, and irregular artifacts start to appear. When the estimated standard deviation is larger than the correct value, the resolution decreases substantially (the image is too smooth). The same effects are demonstrated for field data from a site near Livermore, California. However, when the correct noise values are known, the Occam's results are independent of the discretization used. A case history of monitoring at an enhanced oil recovery site is used to illustrate problems in comparing successive images over time from a site where the noise level changes. In this case, changes in image resolution can be misinterpreted as actual geoelectrical changes. One solution to this problem is to perform smoothest, but non-Occam's, inversion on later data sets using parameters found from the background data set.

459 citations

Journal ArticleDOI
Resistivity modelling for arbitrarily shaped two-dimensional structures

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A. Dey1, H. F. Morrison1
University of California, Berkeley1
01 Mar 1979-Geophysical Prospecting
TL;DR: In this article, a numerical technique is developed to solve the three-dimensional potential distribution about a point source of current located in or on the surface of a half-space containing arbitrary two-dimensional conductivity distribution.
Abstract: A numerical technique is developed to solve the three-dimensional potential distribution about a point source of current located in or on the surface of a half-space containing arbitrary two-dimensional conductivity distribution. Finite difference equations are obtained for Poisson's equations by using point- as well as area-discretization of the subsurface. Potential distributions at all points in the set defining the half-space are simultaneously obtained for multiple point sources of current injection. The solution is obtained with direct explicit matrix inversion techniques. An empirical mixed boundary condition is used at the “infinitely distant” edges of the lower half-space. Accurate solutions using area-discretization method are obtained with significantly less attendant computational costs than with the relaxation, finite-element, or network solution techniques for models of comparable dimensions.

407 citations

"2.5D resistivity modeling of embank..." refers methods in this paper

  • ...Such 2.5D modeling is simply accomlished by involving the inverse Fourier transform for an electrode rray parallel to the strike direction Dey and Morrison, 1979a, b; ueralt et al., 1991 ....

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Frequently Asked Questions (1)
Q1. What contributions have the authors mentioned in the paper ".5d resistivity modeling of embankment dams to assess nfluence from geometry and material properties" ?

This study is part of a project to improve current longterm monitoring routines and data interpretation and increasing the understanding when interpreting existing data. The study evaluates the influence from 3D effects created by specific dam geometry and effects of water level fluctuations in the reservoir.