Airborne geophysical mapping as an innovative methodology for landslide investigation: evaluation of results from the Gschliefgraben landslide, Austria

Supper, R.; Baroň, Ivo; Ottowitz, David; Motschka, K.; Gruber, S.; Winkler, E.; Jochum, Birgit; Römer, A.

doi:10.5194/nhess-13-3313-2013

Cited by 16 publications

(9 citation statements)

References 13 publications

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“…Review papers by Dahlin (2001) for direct current (DC) methods and Tekzan (1999) and Everett (2012) for induction EM methods provide overviews of the large range of applications in which near-surface geologic information is useful. Among the most recent studies, one can find various applications such as aquifer vul-nerability mapping (Röttger et al, 2005), landslide hazards (Pfaffhuber et al, 2010;Supper et al, 2013), clay mapping (Donohue et al, 2012), agriculture regulation (Refsgaard et al, 2014), and overburden mapping Oluwafemi and Oladunjoye, 2013). Most of those studies rely on the mapping of clay geologic units because of their particular mechanical and hydraulic properties, which play key roles in geotechnical (e.g., landslides, construction) and hydrogeological (e.g., groundwater flow modeling, pollution plumes) problems.…”

Section: Introductionmentioning

confidence: 99%

Assessment of near-surface mapping capabilities by airborne transient electromagnetic data — An extensive comparison to conventional borehole data

et al. 2014

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A newly developed helicopter transient electromagnetic (TEM) system has the ability to measure very early times within just a few μs after the turn off of the primary current. For such a system, careful calibration and accurate modeling of the electromagnetic (EM) response is critical to get true resistivities of the very shallow geologic layers. We discovered that this leads to resolution of the same level or in some cases even better than what can be obtained from airborne frequency EM systems. This allowed a range of important applications where high and accurate resolution is mandatory, e.g., geotechnical applications such as urban planning, railroad and road investigations, landslides or distribution of raw materials, and assessing aquifer vulnerability. We evaluated the results of a pilot survey covering the Norsminde catchment south of Aarhus, Denmark, where we found that near-surface layers (top 30 m) can be mapped with an accuracy of a few meters in a complicated glacial sedimentary environment. The mapping of the geologic layers was assessed by a detailed analysis in which we developed a general methodology for crosschecking the EM and borehole data. This methodology is general and can easily be adapted to other data types and surveys. After rating the quality of the boreholes based on a list of predefined criteria, we concluded that the EM data matched with about three-quarters of the boreholes located within less than 15 m from the closest EM soundings. The remaining quarter of the boreholes fell into two groups in which half of the boreholes were of very poor quality or had inaccurate coordinates. Only eight of all the boreholes could not be reproduced by the data, and we attributed this to be caused by very strong lateral or vertical geologic variations not resolvable by the TEM technique.

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Section: Introductionmentioning

confidence: 99%

Assessment of near-surface mapping capabilities by airborne transient electromagnetic data — An extensive comparison to conventional borehole data

et al. 2014

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“…Thus, it would be essential to verify low-resistance bodies located at approximately 5 Ω.m between a depth of 10 and 50 m. The two examples of the La Médaille landslide and the Morne-Figue area show that under landslides, some low resistivity formations could play the role of aquifers concentrating underground flows, punctually recharging the upper layers and influencing the activity of slope instabilities. The study of these bodies over the whole island, in correlation with recent hydrological studies [12,30] using AEM data, must be considered to better define this role on landslides [46]. It may be possible to refine the knowledge of unstable slopes from this information.…”

Section: Discussionmentioning

confidence: 98%

“…Airborne electromagnetics (AEM) provides information on lithology and regolith over large surfaces and/or hard-to-access areas [36][37][38][39][40]. It is able to provide plentiful pseudo-3D information about geological structures reaching a few hundred meters [41,42] and has been successfully used in many environmental studies [30,[43][44][45][46][47] particularly in volcanic settings. AEM is therefore useful to analyze the internal structure of large landslides [48][49][50][51].…”

Section: Introductionmentioning

confidence: 99%

Airborne Electromagnetics to Improve Landslide Knowledge in Tropical Volcanic Environments

2021

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Caribbean areas are particular volcanic territories in tropical environments. These territories juxtapose several landslide-prone areas with different predisposing factors (poorly consolidated volcanic materials, superimposition of healthy materials on highly weathered materials, high heterogeneity of thicknesses, etc.). In these environments, where rapid development of slopes and land use changes are noticeable, it is necessary to better characterize these unstable phenomena that cause damage to infrastructure and people. This characterization has to be carried out on the materials as well as on the initiation conditions of the phenomena and requires complementary investigations. This study, focusing on La Martinique, proposes a landslide analysis methodology that combines new information about landslide-prone materials acquired by an airborne electromagnetics survey with a physical-based model. Once the data are interpreted and compared with field observations and previous data, a geological model is produced and introduced into the physical model to test different instability scenarios. The results show that geophysical investigations (i) improve the knowledge of the internal structure of landslides and surficial formations, (ii) specify the spatial limits of the materials that are sensitive to landslides, and (iii) give a better understanding of landslide initiation conditions, particularly hydrogeological triggering conditions.

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“…The magnetic method is widely used for mapping important targets in mineral and hydrocarbon exploration projects [1][2][3], and data can be acquired in the air, on the ocean, from the ground, and in borehole, for a wide range of geological purposes [4]. Modern aeromagnetic survey is capable of mapping valuable geologic structures on a regional scale including concealed terrains due to the sophistication of modern technology to provide highquality data [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Existence of subsurface structures from aeromagnetic data interpretation of the crustal architecture around Ibi, Middle Benue, Nigeria

Salawu¹,

Orosun

Adebiyi

et al. 2020

SN Appl. Sci.

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Aeromagnetic data acquired over Ibi area within the Middle Benue Trough, Nigeria, has been interpreted to successfully mapped regional structural features that are favorable for economic mineral deposits. The 3D Euler deconvolution technique provided estimated depth values for the regional structural features while the deduced source parameter imaging gave depth estimates to magnetic basement of the study area. The latter map shows two major sub-basins with depth values between 2700 m and 3300 m. Since the magnetic basement depth estimates could be used as a proxy for the thickness of sedimentary formation of the region, the sedimentary formation is sufficiently thick for fossil maturation and therefore confirms that hydrocarbon exploration may be plausible within the region. The combined assessment of magnetic source edge location and magnetic basement depth values offers valuable information on the subsurface configuration, which is very important for mineral and hydrocarbon exploration within Ibi area.subsurface geologic information which is essential for mineral and hydrocarbon exploration projects within Ibi area of Taraba state.Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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Airborne geophysical mapping as an innovative methodology for landslide investigation: evaluation of results from the Gschliefgraben landslide, Austria

Cited by 16 publications

References 13 publications

Assessment of near-surface mapping capabilities by airborne transient electromagnetic data — An extensive comparison to conventional borehole data

Assessment of near-surface mapping capabilities by airborne transient electromagnetic data — An extensive comparison to conventional borehole data

Airborne Electromagnetics to Improve Landslide Knowledge in Tropical Volcanic Environments

Existence of subsurface structures from aeromagnetic data interpretation of the crustal architecture around Ibi, Middle Benue, Nigeria

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