Faulting and groundwater in a desert environment: constraining hydrogeology using time‐domain electromagnetic data

Bedrosian, Paul A.; Burgess, Matt; Nishikawa, Tracy

doi:10.3997/1873-0604.2013043

Cited by 9 publications

(4 citation statements)

References 32 publications

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“…Both inversion approaches employ one‐dimensional (1‐D) physics, in which resistivity is assumed to only vary with depth. Although lateral contrasts in resistivity most certainly occur, the 1‐D modeling assumption is generally a valid approximation except within 100–300 m of a sharp lateral resistivity contact (Bedrosian et al., 2013). We used a deterministic spatially constrained inversion (SCI) and laterally constrained inversion (LCI) (Auken et al., 2015) carried out with Aarhus Workbench software (Aarhus Geosoftware) as well as a Bayesian Markov‐chain Monte Carlo (MCMC) inversion implemented in the open‐source U.S. Geological Survey code Geophysical Bayesian Inference in Python (GeoBIPy; Minsley, 2011; Minsley et al., 2020; Table S2).…”

Section: Methodsmentioning

confidence: 99%

Airborne Geophysical Imaging of Weak Zones on Iliamna Volcano, Alaska: Implications for Slope Stability

2021

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Water‐saturated, hydrothermally altered rocks reduce the strength of volcanic edifices and increase the potential for sector collapses and far‐traveled mass flows of unconsolidated debris. Iliamna Volcano is an andesitic stratovolcano located on the western side of the Cook Inlet, ∼225 km southwest of Anchorage and is a source of repeated avalanches. The widespread snow and ice cover on Iliamna Volcano make surface alteration difficult to identify. However, intense hydrothermal alteration significantly reduces both the electrical resistivity and magnetization of volcanic rock and can therefore be identified with airborne geophysical measurements. We use airborne electromagnetic and magnetic data to map snow and ice thickness and identify underlying alteration zones at Iliamna Volcano, Alaska. Resistivities were calculated to an average depth of >300 m, and a 3‐D susceptibility model extends from the surface to the base of the volcano, about 3,000 m below the summit. Geophysical models image low resistivity (<30 ohm‐m) and low susceptibilities near the summit of Iliamna and below its older vent complex, with the low susceptibilities indicating alteration up to ∼800 m in thickness. Thin conductors (∼50–100 m thick) on the edifice slopes coincide with recorded locations of repeated debris avalanches over the past ∼60 years and are attributed to saturated zones at high elevation. Three‐dimensional slope stability models based upon the geophysically constrained alteration distribution suggest the edifice of Iliamna is unstable and could lead to collapse scars ∼400 m deep near the current and former vent complexes.

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Section: Methodsmentioning

confidence: 99%

Airborne Geophysical Imaging of Weak Zones on Iliamna Volcano, Alaska: Implications for Slope Stability

2021

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“…TDEM method provides the measure the electrical resistivity distribution of the ground through the induction of eddy currents in the subsoil (Christiansen et al, ; Nabighian & Macnae, ). It is widely used to image the electrical properties of subsurface geological structures over different lithological settings with the capability to reach significant penetration depths over moderately resistive environments (few hundreds of meters; Bedrosian et al, ). We follow the approach by Civico et al () to map the top bedrock depths using 1‐D vertical resistivity models.…”

Section: Methodsmentioning

confidence: 99%

Geometry and Structure of a Fault‐Bounded Extensional Basin by Integrating Geophysical Surveys and Seismic Anisotropy Across the 30 October 2016 M_w 6.5 Earthquake Fault (Central Italy): The Pian Grande di Castelluccio Basin

et al. 2019

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The Pian Grande di Castelluccio (PGC) basin is the main Quaternary depocenter of the Mt.Vettore-Mt. Bove normal fault system (VBFS), responsible for the 30 October 2016 M w 6.5 Norcia earthquake (central Italy). Coseismic surface faulting through the basin attests the occurrence of active splays of the seismogenic master fault; thus, we explore the subsurface basin structure to infer the long-term behavior of the VBFS. We integrate electrical resistivity tomography (ERT), time domain electromagnetic soundings (TDEM), and horizontal-to-vertical spectral ratios of ambient seismic vibrations (HVSR) along a transect crossing the surface ruptures. The ERT models provide high-resolution details of three shallow fault zones. One-dimensional resistivity models from TDEM and HVSR frequency peaks suggest abrupt steps in the top bedrock caused by previously unknown faults and indicate an infill thickness of up to~300 m. We also analyze shear wave splitting of S phases (fast direction φ and delay time δt) from local earthquakes recorded during our surveys to better constrain the fracture field and the properties of the inferred fault zones. We relate the retrieved pattern of fault-parallel φ, and the associated larger δt, to the main and secondary faults in the upper crust and to the cracks or shear fabric in the damage zones of the active splays. The PGC basin is due to the interference of an older N30°striking fault system subsequently crosscut by the N150°striking VBFS, which is currently active, seismogenic, and capable of rupturing the surface during M > 6 earthquakes. 2009; Burbank & Anderson, 2011). Hence, the basins' geometry and depositional architecture provide basic VILLANI ET AL.26

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“…In fact, the ratio of penetration depth to loop size for TDEM can be much greater than 1, as opposed to electrical resistivity tomography, where great penetration depths require long electrode arrays [ Revil et al ., ; Pucci et al ., ]. Ground TDEM surveys were rarely used in the recent past to map fault zone [e.g., Bedrosian et al ., ] or for depth‐to‐bedrock investigations over a fault‐controlled area [e.g., Bedrosian et al ., ].…”

Section: Methods and Data Acquisitionmentioning

confidence: 99%

Geometry and evolution of a fault‐controlled Quaternary basin by means of TDEM and single‐station ambient vibration surveys: The example of the 2009 L'Aquila earthquake area, central Italy

et al. 2017

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We applied a joint survey approach integrating time domain electromagnetic soundings and single‐station ambient vibration surveys in the Middle Aterno Valley (MAV), an intermontane basin in central Italy and the locus of the 2009 L'Aquila earthquake. By imaging the buried interface between the infilling deposits and the top of the pre‐Quaternary bedrock, we reveal the 3‐D basin geometry and gain insights into the long‐term basin evolution. We reconstruct a complex subsurface architecture, characterized by three main depocenters separated by thresholds. Basin infill thickness varies from ~200–300 m in the north to more than 450 m to the southeast. Our subsurface model indicates a strong structural control on the architecture of the basin and highlights that the MAV experienced considerable modifications in its configuration over time. The buried shape of the MAV suggests a recent and still ongoing predominant tectonic control by the NW‐SE trending Paganica‐San Demetrio Fault System (PSDFS), which crosscuts older ~ENE and NNE trending extensional faults. Furthermore, we postulate that the present‐day arrangement of the PSDFS is the result of the linkage of two previously isolated fault segments. We provide constraints on the location of the southeastern boundary of the PSDFS, defining an overall ~19 km long fault system characterized by a considerable seismogenetic potential and a maximum expected magnitude larger than M 6.5. This study emphasizes the benefit of combining two easily deployable geophysical methods for reconstructing the 3‐D geometry of a tectonically controlled basin. Our joint approach provided us with a consistent match between these two independent estimations of the basin substratum depth within 15%.

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Faulting and groundwater in a desert environment: constraining hydrogeology using time‐domain electromagnetic data

Cited by 9 publications

References 32 publications

Airborne Geophysical Imaging of Weak Zones on Iliamna Volcano, Alaska: Implications for Slope Stability

Airborne Geophysical Imaging of Weak Zones on Iliamna Volcano, Alaska: Implications for Slope Stability

Geometry and Structure of a Fault‐Bounded Extensional Basin by Integrating Geophysical Surveys and Seismic Anisotropy Across the 30 October 2016 M_w 6.5 Earthquake Fault (Central Italy): The Pian Grande di Castelluccio Basin

Geometry and evolution of a fault‐controlled Quaternary basin by means of TDEM and single‐station ambient vibration surveys: The example of the 2009 L'Aquila earthquake area, central Italy

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Faulting and groundwater in a desert environment: constraining hydrogeology using time‐domain electromagnetic data

Cited by 9 publications

References 32 publications

Airborne Geophysical Imaging of Weak Zones on Iliamna Volcano, Alaska: Implications for Slope Stability

Airborne Geophysical Imaging of Weak Zones on Iliamna Volcano, Alaska: Implications for Slope Stability

Geometry and Structure of a Fault‐Bounded Extensional Basin by Integrating Geophysical Surveys and Seismic Anisotropy Across the 30 October 2016 Mw 6.5 Earthquake Fault (Central Italy): The Pian Grande di Castelluccio Basin

Geometry and evolution of a fault‐controlled Quaternary basin by means of TDEM and single‐station ambient vibration surveys: The example of the 2009 L'Aquila earthquake area, central Italy

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Geometry and Structure of a Fault‐Bounded Extensional Basin by Integrating Geophysical Surveys and Seismic Anisotropy Across the 30 October 2016 M_w 6.5 Earthquake Fault (Central Italy): The Pian Grande di Castelluccio Basin