Determination of the permeability of seepage flow paths in dams from self-potential measurements

Ahmed, A. Soueid; Revil, A.; Bolève, A.; Steck, B.; Vergniault, Christophe; Courivaud, Jean-Robert; Jougnot, Damien; Abbas, Micheline

doi:10.1016/j.enggeo.2020.105514

Cited by 39 publications

(10 citation statements)

References 39 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Finally, the streaming potentials need to be analyzed with regard to not only time but also space, given the large surface and subsurface heterogeneities in mountainous areas. Here, methods ranging from simple to advanced could be used, correlating the orientation of specific dipoles to water flow (simple) or applying advanced tomographic algorithms to pro-duce 3D subsurface water flow patterns from measured SP signals (e.g., Jardani et al, 2007;Ahmed et al, 2013Ahmed et al, , 2020. Any inversion of the data would also enable further analysis with regard to a successful extraction of process signatures.…”

Section: Monitoring Of Streaming Potentials In Alpine Permafrostmentioning

confidence: 99%

“…Fluid flow in porous media generates electrical potential gradients, so-called streaming potentials, commonly antiparallel to the fluid pressure gradient (e.g., Telford et al, 1990;Bernabé, 1998;Revil et al, 2012). The electrical charge separation, required to build up these potentials, happens at the shear plane of the so-called electrical double layer (EDL), which is a multilayered ion concentration gradient structure that forms at the interface of charged surfaces and bipolar liquids (e.g., Revil et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

“…The HS equation was initially developed only for capillary flow but was later shown to also work for porous media with arbitrary pore space geometry, as long as the surface conductivity of the subsurface is small compared to the fluid conductivity (e.g., Morgan et al, 1989;Bernabé, 1998;Jougnot et al, 2019). In order to formulate the problem for a spatially variable flow (and thus electrical potential) field, a formulation based on transport equations for representative volumes of electrical and fluid flow is used (e.g., Jardani et al, 2007;Jougnot et al, 2020, and references therein).…”

Section: Introductionmentioning

confidence: 99%

“…Passive SP signatures have been used to assess a multitude of different research questions, such as the long-term investigation of unsaturated water flow in lysimeters (e.g., Doussan et al, 2002), characterizing pumping experiments (e.g., DesRoches and Butler, 2016;DesRoches et al, 2018, and references therein), assessing earthquake triggers (e.g., Bernabé, 1998;Guzmán-Vargas et al, 2009, and references therein), characterizing dams (e.g., Moore et al, 2011), and monitoring volcanoes (e.g., Maio et al, 1997;Friedel et al, 2004). Water flow in and around trees has also been investigated in some long-term experiments using the SP method (e.g., Gibert et al, 2006;Voytek et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

A monitoring system for spatiotemporal electrical self-potential measurements in cryospheric environments

Weigand

Wagner

Limbrock

et al. 2020

Geosci. Instrum. Method. Data Syst.

View full text Add to dashboard Cite

Abstract. Climate-induced warming increasingly leads to degradation of high-alpine permafrost. In order to develop early warning systems for imminent slope destabilization, knowledge about hydrological flow processes in the subsurface is urgently needed. Due to the fast dynamics associated with slope failures, non- or minimally invasive methods are required for inexpensive and timely characterization and monitoring of potential failure sites to allow in-time responses. These requirements can potentially be met by geophysical methods usually applied in near-surface geophysical settings, such as electrical resistivity tomography (ERT), ground-penetrating radar (GPR), various seismic methods, and self-potential (SP) measurements. While ERT and GPR have their primary uses in detecting lithological subsurface structure and liquid water/ice content variations, SP measurements are sensitive to active water flow in the subsurface. Combined, these methods provide huge potential to monitor the dynamic hydrological evolution of permafrost systems. However, while conceptually simple, the technical application of the SP method in high-alpine mountain regions is challenging, especially if spatially resolved information is required. We here report on the design, construction, and testing phase of a multi-electrode SP measurement system aimed at characterizing surface runoff and meltwater flow on the Schilthorn, Bernese Alps, Switzerland. Design requirements for a year-round measurement system are discussed; the hardware and software of the constructed system, as well as test measurements are presented, including detailed quality-assessment studies. On-site noise measurements and one laboratory experiment on freezing and thawing characteristics of the SP electrodes provide supporting information. It was found that a detailed quality assessment of the measured data is important for such challenging field site operations, requiring adapted measurement schemes to allow for the extraction of robust data in light of an environment highly contaminated by anthropogenic and natural noise components. Finally, possible short- and long-term improvements to the system are discussed and recommendations for future installations are developed.

show abstract

Section: Monitoring Of Streaming Potentials In Alpine Permafrostmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A monitoring system for spatiotemporal electrical self-potential measurements in cryospheric environments

Weigand

Wagner

Limbrock

et al. 2020

Geosci. Instrum. Method. Data Syst.

View full text Add to dashboard Cite

show abstract

“…They have been applied to landslides and earthflows by various researchers (e.g., Schmutz et al, 2000Schmutz et al, , 2009Hibert et al, 2012;Malehmir et al, 2013). In the realm of hydrogeophysics, self-potential and induced polarization are two geophysical methods offering useful information to characterize ground water flow (e.g., Soueid Ahmed et al, 2020a), water and clay contents (Soueid Ahmed et al, 2020b), and permeability (Titov et al, 2010;Revil and Florsch, 2010;Soueid Ahmed et al, 2014;Weller et al, 2015), all essential ingredients to better understand and prevent landslides. Induced polarization refers to the study of both conductivity and low-frequency polarization properties of rocks.…”

Section: Introductionmentioning

confidence: 99%

Induced polarization as a tool to characterize shallow landslides

Revil

Ahmed

Coperey

et al. 2020

Journal of Hydrology

Self Cite

View full text Add to dashboard Cite

The development of shallow landslides is strongly connected to the changes in the water content of soils on hillslopes, their clay content and permeability distribution, which, in turn, are playing an important role regarding their hydro-mechanical properties. A non-intrusive geophysical method able to map these properties would be very helpful. The most common geoelectrical method, DC (Direct Current) resistivity, cannot be used as a stand-alone technique for this purpose since it depends on two contributions (bulk and surface conductivities), which depend on the water content and the cation exchange capacity (CEC) of the material. Induced polarization is a geophysical method that can be now used to complement DC resistivity in providing key material properties that can be used to diagnose potential risks for failure. We first recall the basic principles behind the induced polarization method from laboratory to field scales and key findings in the underlying petrophysics needed to jointly interpret electrical conductivity and normalized chargeability tomograms. Then, we apply these relationships to a field survey carried out over a shallow landslide at Claix (Isère, France), close to Grenoble. A 3D induced polarization survey was carried out and interpreted in terms of the clay content, water content, and permeability distributions. We demonstrate that the landslide is associated with a channel of high water content corresponding with the presence of travertine, a flow-path, and a permeability barrier downslope corresponding to the presence of plastic clays. This study demonstrates that induced polarization can be used to characterize the impacted volume and therefore might have been useful to map the area before the landslide to assess the possible risk of failure. This methodology could play a key role in mitigation planning.

show abstract

Flow-field fitting method and acoustic Doppler velocity measurement: a new approach and its application to the detection of leakage pathways in the concrete face rockfill dam

Zhao

Zhang

Wei

et al. 2021

Preprint

View full text Add to dashboard Cite

Determination of the permeability of seepage flow paths in dams from self-potential measurements

Cited by 39 publications

References 39 publications

A monitoring system for spatiotemporal electrical self-potential measurements in cryospheric environments

A monitoring system for spatiotemporal electrical self-potential measurements in cryospheric environments

Induced polarization as a tool to characterize shallow landslides

Flow-field fitting method and acoustic Doppler velocity measurement: a new approach and its application to the detection of leakage pathways in the concrete face rockfill dam

Contact Info

Product

Resources

About