Best practices for using electrical resistivity tomography to investigate permafrost

Herring, Teddi; Lewkowicz, Antoni G.; Hauck, Christian; Hilbich, Christin; Mollaret, Coline; Oldenborger, Greg A.; Uhlemann, Sebastian; Farzamian, Mohammad; Calmels, Fabrice; Scandroglio, Riccardo

doi:10.1002/ppp.2207

Cited by 15 publications

(15 citation statements)

References 194 publications

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“…In the event that the proposed criteria do not fully remove all bad measurements, additional processing criteria, suggested by Herring et al. (2023), can be implemented based on the data quality.…”

Section: Resultsmentioning

confidence: 99%

Advancing Permafrost Monitoring With Autonomous Electrical Resistivity Tomography (A‐ERT): Low‐Cost Instrumentation and Open‐Source Data Processing Tool

Farzamian,

Blanchy,

McLachlan

et al. 2024

Geophysical Research Letters

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Permafrost is a widespread phenomenon in the cold regions of the globe and is under‐represented in global monitoring networks. This study presents a novel low‐cost, low‐power, and robust Autonomous Electrical Resistivity Tomography (A‐ERT) monitoring system and open‐source processing tools for permafrost monitoring. The processing workflow incorporates diagnostic and filtering tools and utilizes open‐source software, ResIPy, for data inversion. The workflow facilitates quick and efficient extraction of key information from large data sets. Field experiments conducted in Antarctica demonstrated the system's capability to operate in harsh and remote environments and provided high‐temporal‐resolution imaging of ground freezing and thawing dynamics. This data set and processing workflow allow for a detailed investigation of how meteorological conditions impact subsurface processes. The A‐ERT setup can complement existing monitoring networks on permafrost and is suitable for continuous monitoring in polar and mountainous regions, contributing to cryosphere research and gaining deeper insights into permafrost and active layer dynamics.

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Section: Resultsmentioning

confidence: 99%

Advancing Permafrost Monitoring With Autonomous Electrical Resistivity Tomography (A‐ERT): Low‐Cost Instrumentation and Open‐Source Data Processing Tool

Farzamian,

Blanchy,

McLachlan

et al. 2024

Geophysical Research Letters

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“…Similar to surface wave methods, ERT technique excels in near-surface permafrost characterization by modeling subsurface resistivity to match observed apparent resistivity data, typically yielding a two-dimensional resistivity profile (Daily et al, 2000). ERT has been used in several permafrost studies to characterize permafrost thaw (Etzelmüller et al, 2020), distinguish ice-content variations (Herring et al, 2023), and examine interactions between permafrost and infrastructure (You et al, 2017). MASW has often been combined with other technologies in permafrost research, such as seismic tomography and ERT (Dou & Ajo-Franklin, 2014;Glazer et al, 2020;Marciniak et al, 2018Marciniak et al, , 2019.…”

Section: Seismic and Geoelectrical Methods In Permafrost Regionsmentioning

confidence: 99%

Mapping Permafrost Variability and Degradation Using Seismic Surface Waves, Electrical Resistivity, and Temperature Sensing: A Case Study in Arctic Alaska

Tourei,

Ji,

Rocha dos Santos

et al. 2024

JGR Earth Surface

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Subsurface processes significantly influence surface dynamics in permafrost regions, necessitating utilizing diverse geophysical methods to reliably constrain permafrost characteristics. This research uses multiple geophysical techniques to explore the spatial variability of permafrost in undisturbed tundra and its degradation in disturbed tundra in Utqiaġvik, Alaska. Here, we integrate multiple quantitative techniques, including multichannel analysis of surface waves (MASW), electrical resistivity tomography (ERT), and ground temperature sensing, to study heterogeneity in permafrost’s geophysical characteristics. MASW results reveal active layer shear wave velocities (Vs) between 240 and 370 m/s, and permafrost Vs between 450 and 1,700 m/s, typically showing a low‐high‐low velocity pattern. Additionally, we find an inverse relationship between in situ Vs and ground temperature measurements. The Vs profiles along with electrical resistivity profiles reveal cryostructures such as cryopeg and ice‐rich zones in the permafrost layer. The integrated results of MASW and ERT provide valuable information for characterizing permafrost heterogeneity and cryostructure. Corroboration of these geophysical observations with permafrost core samples’ stratigraphies and salinity measurements further validates these findings. This combination of geophysical and temperature sensing methods along with permafrost core sampling confirms a robust approach for assessing permafrost’s spatial variability in coastal environments. Our results also indicate that civil infrastructure systems such as gravel roads and pile foundations affect permafrost by thickening the active layer, lowering the Vs, and reducing heterogeneity. We show how the resulting Vs profiles can be used to estimate key parameters for designing buildings in permafrost regions and maintaining existing infrastructure in polar regions.

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“…ERT is a well-established method to image the two-dimensional distribution of electrical properties of subsurface mountain permafrost and ground ice due to its sensitivity and suitability to distinguish unfrozen material, ice-containing permafrost (excess ice), and massive sedimentary ice due to their contrasting electrical properties (e.g. Haeberli and Vonder Mühll, 1996;Hauck and Kneisel, 2008;Bosson et al, 2015;Halla et al, 2021;Herring et al, 2023).…”

Section: Electrical Resistivity Tomography (Ert)mentioning

confidence: 99%

Characterizing ground ice content and origin to better understand the seasonal surface dynamics of the Gruben rock glacier and the adjacent Gruben debris-covered glacier (southern Swiss Alps)

Wee,

Vivero,

Mathys

et al. 2024

Preprint

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Abstract. Over the recent years, there has been focused international efforts to coordinate the development and compilation of rock glacier inventories. Nevertheless, in some contexts, identifying and characterizing rock glaciers can be challenging as complex conditions and interactions, such as glacier-rock glacier interactions, can yield landforms or landform assemblages that are beyond a straightforward interpretation and classification through ordinary visual means alone. To gain a better understanding of the spatial and temporal complexity of the ongoing processes where glacier-permafrost interactions have occurred, the characterization of the subsurface of the Gruben rock glacier and its adjacent complex contact zone is quantitively assessed using a petrophysical joint inversion (PJI) scheme, based on electrical resistivity (ERT) and refraction seismic (RST) data. Surface dynamics are assessed using both in-situ and close-range remote sensing techniques to monitor daily and seasonal displacements and to monitor landform-wide surface changes at high spatial resolution, respectively. Both the geophysical and geodetic surveys allowed to identify two zones: the rock glacier zone and the complex contact zone where both permafrost and embedded surface ice are present. In the complex contact zone extremely high ice contents (estimated up to 85 %) were found. Widespread supersaturated permafrost conditions were found in the rock glacier zone. Surface displacement rates in this zone are typical of permafrost creep behaviour, with a gradual acceleration in late spring and a gradual deceleration in winter. Moreover, the coherent nature of the rock glacier zone surface deformation contrasts with the back-creeping and slightly chaotic surface deformation of the complex contact zone. Favouring a multi-method approach allowed a detailed representation of the spatial distribution of ground ice content and origin, which enabled to discriminate glacial from periglacial processes as their spatio-temporal patterns of surface change and geophysical signatures are (mostly) different.

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Best practices for using electrical resistivity tomography to investigate permafrost

Cited by 15 publications

References 194 publications

Advancing Permafrost Monitoring With Autonomous Electrical Resistivity Tomography (A‐ERT): Low‐Cost Instrumentation and Open‐Source Data Processing Tool

Advancing Permafrost Monitoring With Autonomous Electrical Resistivity Tomography (A‐ERT): Low‐Cost Instrumentation and Open‐Source Data Processing Tool

Mapping Permafrost Variability and Degradation Using Seismic Surface Waves, Electrical Resistivity, and Temperature Sensing: A Case Study in Arctic Alaska

Characterizing ground ice content and origin to better understand the seasonal surface dynamics of the Gruben rock glacier and the adjacent Gruben debris-covered glacier (southern Swiss Alps)

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