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

Peterson, D. E.; Finn, Carol A.; Bedrosian, Paul A.

doi:10.1029/2020jb020807

Cited by 12 publications

(7 citation statements)

References 82 publications

(159 reference statements)

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“…When modeling a homogeneous subsurface property distribution the most likely flank to collapse was estimated to be the north-western flank, however, when incorporating rock alterations mapped by the AEM data, the south-eastern flank was estimated to having a higher susceptibility to failure. Similar results where also obtained by Peterson et al (2021), which show that particularly deep hydro-thermal alteration of the Iliamna Volcano considerably increases the susceptibility of slope failure, but also increases the potential volume of material that could be released during failure (Fig. 18).…”

Section: Process-based Inversionsupporting

confidence: 85%

“…Yet, in contrast to vadose zone or groundwater studies, where many process-based inversion approaches have been developed and used, in the field of natural hazards this is only now starting to emerge. Some recent studies have combined subsurface structures identified from airborne EM data with hydro-geomechanical models to assess the stability of volcano flanks (Peterson et al, 2021;Finn et al, 2018). By incorporating subsurface features into the slope stability model, Finn et al (2018) could improve the hazards assessment for slope failure of Mt.…”

Section: Process-based Inversionmentioning

confidence: 99%

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An overview of multimethod imaging approaches in environmental geophysics

Wagner

Uhlemann

2021

Advances in Geophysics

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Quantitative characterization of subsurface properties is critical for many environmental applications and serves as the basis to simulate and better understand dynamic subsurface processes. Geophysical imaging methods allow to image subsurface property distributions and monitor their spatio-temporal changes in a minimally-invasive manner. While it is widely agreed upon that models integrating multiple independent data sources are more reliable, the number of approaches to do so is increasing rapidly and often overwhelming for researchers and, particularly, novices to the field.With this work, we aim to contribute to the development multi-method imaging through (1) an overview of, and didactic introduction to, existing inversion approaches for the integration of multiple geophysical data sets with other measurement types (e.g., hydrological observations), petrophysical models, and process simulations, (2) a state-of-the-art review on the use and potentials of these approaches in various environmental applications, and (3) a discussion on new frontiers and remaining challenges in the field.We hope that this chapter provides an entry point to recent developments in multimethod geophysical imaging, clarifies similarities, differences and development potentials of existing approaches, and ultimately helps practitioners to choose the optimum one to integrate their data sets.

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Section: Process-based Inversionsupporting

confidence: 85%

Section: Process-based Inversionmentioning

confidence: 99%

An overview of multimethod imaging approaches in environmental geophysics

Wagner

Uhlemann

2021

Advances in Geophysics

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“…For example, using AEM data, subsurface properties in Alaska over an area of about 300 km 2 have been estimated (31). Within the last few years, AEM surveys are covering increasingly larger areas at regional basin scales, as large as 140,000 km 2 (32), and are moving from predominantly flat areas [e.g., (33,34)] to mountainous environments (35)(36)(37). There is an increased effort to use AEM data to construct hydrological models from local to regional scales (38)(39)(40).…”

Section: Introductionmentioning

confidence: 99%

Surface parameters and bedrock properties covary across a mountainous watershed: Insights from machine learning and geophysics

et al. 2022

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Bedrock property quantification is critical for predicting the hydrological response of watersheds to climate disturbances. Estimating bedrock hydraulic properties over watershed scales is inherently difficult, particularly in fracture-dominated regions. Our analysis tests the covariability of above- and belowground features on a watershed scale, by linking borehole geophysical data, near-surface geophysics, and remote sensing data. We use machine learning to quantify the relationships between bedrock geophysical/hydrological properties and geomorphological/vegetation indices and show that machine learning relationships can estimate most of their covariability. Although we can predict the electrical resistivity variation across the watershed, regions of lower variability in the input parameters are shown to provide better estimates, indicating a limitation of commonly applied geomorphological models. Our results emphasize that such an integrated approach can be used to derive detailed bedrock characteristics, allowing for identification of small-scale variations across an entire watershed that may be critical to assess the impact of disturbances on hydrological systems.

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“…As the technology develops, AEM survey has been applied extensively in groundwater detection (Ball et al., 2020; Klee, 2013; Mikucki et al., 2015; Minsley et al., 2021; Thomsen et al., 2004; Viezzoli et al., 2010), mineral exploration (Koné et al., 2021; Okada, 2020; Roach et al., 2014), urban investigation (Steuer et al., 2020) and geological mapping (Dzikunoo et al., 2020; Jordan et al., 2009; Ley‐Cooper & Brodie, 2020; Rey et al., 2019; Silvestri et al., 2019; Wong et al., 2020). Recently, it has been exploited specifically in confined aquifer detection (Dugan et al., 2015), subglacial hydrology (Blatter et al., 2018), and volcano hazards (Dumont et al., 2019; Peterson et al., 2021).…”

Section: Introductionmentioning

confidence: 99%

Instantaneous Inversion of Airborne Electromagnetic Data Based on Deep Learning

Huang

Zhao

2022

Geophysical Research Letters

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Detailed understanding of subsurface structure is necessary and leads to tremendous benefits on both sustainable resource management and hazard mitigation. Geophysical techniques offer non-invasive access to subsurface characteristics (Slater, 2015). Variations in several medium properties, such as mineral composition and water saturation, are prominently reflected in conductivity anomalies which can be detected with electromagnetic measurements (Vozoff, 1980). However, ground-based observations are often impeded by complex landforms, including rugged terrains, vegetation and water bodies, and can even be inaccessible in certain scenarios such as fault zones, volcanic areas and glaciers. Consequently, airborne electromagnetic (AEM) technology gains in popularity with its significant adaptability to drastic topography (Auken et al., 2017). Moreover, AEM has many other advantages, such as acquisition efficiency and wide spatial coverage. The AEM system utilizes a set of transmitting and receiving coils suspended below the aircraft to transmit repeated emission current and measure the induced secondary electromagnetic fields after the current is cut off (Christiansen et al., 2006). The recorded time series in turn decays exponentially over time due to ohmic loss and downward propagation and shows great sensitivity to conductivity anomalies. As the technology develops, AEM survey has been applied extensively in groundwater detection (

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

Cited by 12 publications

References 82 publications

An overview of multimethod imaging approaches in environmental geophysics

An overview of multimethod imaging approaches in environmental geophysics

Surface parameters and bedrock properties covary across a mountainous watershed: Insights from machine learning and geophysics

Instantaneous Inversion of Airborne Electromagnetic Data Based on Deep Learning

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