Review: Some low-frequency electrical methods for subsurface characterization and monitoring in hydrogeology

Revil, A.; Karaoulis, M.; Johnson, Timothy C.; Kemna, Andreas

doi:10.1007/s10040-011-0819-x

Cited by 269 publications

(198 citation statements)

References 245 publications

Supporting

Mentioning

186

Contrasting

Unclassified

Order By: Relevance

“…The bulk electrical conductivity (σ b ) includes contributions from the electrical conductivity of pore water and the surface conduction at the pore and water-mineral interface (Revil et al, 2012). We employed the model proposed by Linde et al (2006), which was extended from Archie's model (Archie, 1942), and is expressed below as…”

Section: Petrophysical Modelmentioning

confidence: 99%

Quantifying shallow subsurface water and heat dynamics using coupled hydrological-thermal-geophysical inversion

Tran

Dafflon

Hubbard

et al. 2016

Hydrol. Earth Syst. Sci.

View full text Add to dashboard Cite

Abstract. Improving our ability to estimate the parameters that control water and heat fluxes in the shallow subsurface is particularly important due to their strong control on recharge, evaporation and biogeochemical processes. The objectives of this study are to develop and test a new inversion scheme to simultaneously estimate subsurface hydrological, thermal and petrophysical parameters using hydrological, thermal and electrical resistivity tomography (ERT) data. The inversion scheme -which is based on a nonisothermal, multiphase hydrological model -provides the desired subsurface property estimates in high spatiotemporal resolution. A particularly novel aspect of the inversion scheme is the explicit incorporation of the dependence of the subsurface electrical resistivity on both moisture and temperature. The scheme was applied to synthetic case studies, as well as to real datasets that were autonomously collected at a biogeochemical field study site in Rifle, Colorado. At the Rifle site, the coupled hydrological-thermal-geophysical inversion approach well predicted the matric potential, temperature and apparent resistivity with the Nash-Sutcliffe efficiency criterion greater than 0.92. Synthetic studies found that neglecting the subsurface temperature variability, and its effect on the electrical resistivity in the hydrogeophysical inversion, may lead to an incorrect estimation of the hydrological parameters. The approach is expected to be especially useful for the increasing number of studies that are taking advantage of autonomously collected ERT and soil measurements to explore complex terrestrial system dynamics.

show abstract

Section: Petrophysical Modelmentioning

confidence: 99%

Quantifying shallow subsurface water and heat dynamics using coupled hydrological-thermal-geophysical inversion

Tran

Dafflon

Hubbard

et al. 2016

Hydrol. Earth Syst. Sci.

View full text Add to dashboard Cite

show abstract

“…The average of the inversion RMS (root mean square) is about 19.3%, which is due chiefly to the field noises from pumping activities and using the 2D inversion scheme for the 3D objects. Factors that can generate noisy measurements in pumping environments include induction in the ground associated with power lines, direct current injection associated with cathodic grounding (Corwin and Hoover 1979), and the metallic casing of a piezometer (Revil et al 2012). These factors are the possible sources that contribute to noisy measurements and higher RMS in the inversion.…”

Section: The Monitoring Configurations For Time-lapse Resistivitymentioning

confidence: 99%

Using the Resistivity Imaging Method to Monitor the Dynamic Effects on the Vadose Zone During Pumping Tests at the Pengtsuo Site in Pingtung, Taiwan

Chang¹,

Hsu²,

Chang³

et al. 2016

Terr. Atmos. Ocean. Sci.

View full text Add to dashboard Cite

We conducted a time-lapse monitoring study during a well-pumping test at the Pengtsuo site in Pingtung, Taiwan. Water-level gauges were installed in four wells (P1, W1, O1, and O2) at the Pengtsuo site with different screen depths for the observation. We designed the pumping test to be executed in three phases: the background, the stepwise-pumping, and the continuous-pumping phases. The survey line crossed the four wells so that a comparison would be possible between the resistivity measurements and the water-level records. The resistivity differences relative to the pre-pumping background show that electrical resistivity imaging (ERI) can resolve changes due to dewatering from pumping activity. The time-lapse resistivity images reveal that the maximum resistivity increase took place at the locations in the vadose zone instead of at the groundwater surface. The variation in the resistivity differences in the vadose zone correlated to the change in groundwater level in the stepwise phase. On the other hand, the resistivity-difference change was not fully consistent with the groundwater-level change in the continuous-pumping phase. We attribute the abnormal ERI signals to the dynamic non-equilibrium of the water movement in the vadose zone. The findings suggest that pumping designs can affect the changing resistivity differences and water-content distribution patterns. We show the potential of the ER method to reveal both the water flow and water-content changes in the vadose zone with different transient boundary conditions.

show abstract

“…Electrical resistivity tomography (ERT) has proven its efficiency to image and/or monitor spatial phenomena [43] such as salt water intrusions [44,45], variations in moisture content (e.g., [46,47]), biodegradation of hydrocarbons (e.g., [48,49]) and salt tracer experiments (e.g., [50,51] and references therein). An in-depth review of electrical properties of rocks can be found in Schön [52] or Revil et al [53], whereas a description of electrical methods can be found in Binley and Kemna [54]. The panel seems slightly heterogeneous and reflects lithological changes.…”

Section: Electrical Resistivity Tomographymentioning

confidence: 99%

Geophysical Methods for Monitoring Temperature Changes in Shallow Low Enthalpy Geothermal Systems

Hermans

Nguyen

Robert³

et al. 2014

Energies

View full text Add to dashboard Cite

Low enthalpy geothermal systems exploited with ground source heat pumps or groundwater heat pumps present many advantages within the context of sustainable energy use. Designing, monitoring and controlling such systems requires the measurement of spatially distributed temperature fields and the knowledge of the parameters governing groundwater flow (permeability and specific storage) and heat transport (thermal conductivity and volumetric thermal capacity). Such data are often scarce or not available. In recent years, the ability of electrical resistivity tomography (ERT), self-potential method (SP) and distributed temperature sensing (DTS) to monitor spatially and temporally temperature changes in the subsurface has been investigated. We review the recent advances in using these three methods for this type of shallow applications. A special focus is made regarding the petrophysical relationships and on underlying assumptions generally needed for a quantitative interpretation of these geophysical data. We show that those geophysical methods are mature to be used within the context of temperature monitoring and that a combination of them may be the best choice regarding control and validation issues. OPEN ACCESSEnergies 2014, 7 5084

show abstract

Review: Some low-frequency electrical methods for subsurface characterization and monitoring in hydrogeology

Cited by 269 publications

References 245 publications

Quantifying shallow subsurface water and heat dynamics using coupled hydrological-thermal-geophysical inversion

Quantifying shallow subsurface water and heat dynamics using coupled hydrological-thermal-geophysical inversion

Using the Resistivity Imaging Method to Monitor the Dynamic Effects on the Vadose Zone During Pumping Tests at the Pengtsuo Site in Pingtung, Taiwan

Geophysical Methods for Monitoring Temperature Changes in Shallow Low Enthalpy Geothermal Systems

Contact Info

Product

Resources

About