Automated Airborne EM and borehole data integration for depth to bedrock extraction

Craig Christensen; Helgard Anschutz; Andreas Pfaffhuber

doi:10.1071/ASEG2015ab256

24th International Geophysical Conference and Exhibition – Geophysics and Geology Together for Discovery

ISSN: 2202-0586
E-ISSN:

oa Automated Airborne EM and borehole data integration for depth to bedrock extraction
Authors Craig Christensen^a, Helgard Anschutz^b and Andreas Pfaffhuber^c
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^a NGI / Queen’s University at Kingston, Sognsveien 72, Oslo, , Norway, [email protected] ^b NGI Sognsveien 72, Oslo, , Norway, [email protected] ^c NGI Sognsveien 72, Oslo, , Norway, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2015, Issue 24th International Geophysical Conference and Exhibition – Geophysics and Geology Together for Discovery, Dec 2015, p. 1 - 5
DOI: https://doi.org/10.1071/ASEG2015ab256
- Published online: 01 Dec 2015

Abstract

Airborne electromagnetic (AEM) was used to supplement a geotechnical investigation for a highway construction project in Norway. Variable bedrock threshold resistivity hindered efforts to track depth to bedrock, motivating us to develop an automated algorithm to extract depth to bedrock from both boreholes and AEM data. We developed two variations of this algorithm: one using simple Gaussian or inverse distance weighting interpolators, and another using ordinary kriging and combined parameter probability distribution functions.

Evaluation shows that for preliminary surveys, significant savings in boreholes required can be made without sacrificing bedrock model accuracy. However, issues with AEM noise and data quality likely reduced the comparative advantage that including AEM provided. Moreover, AEM cannot supersede direct sampling where the model accuracy required exceed the resolution possible with the geophysical method. Nevertheless, using AEM in the way can still reduce the number of required boreholes and hence reduce site investigation costs because we can identify high probability zones for shallow bedrock, identify steep or anomalous bedrock topography, and estimate the spatial variability of depth.

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2015-12-01

2026-01-22

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References

Chouteau, M., Boudour, Z., Parent, M., and Marcotte, D., 2013, Estimation of overburden thickness using airborne time-domain EM data and a few drill hole data: 13th SAGA Biennial Conference and Exhibition. Mpumalanga, South Africa: South African Geophysical Association.
Foged, N., 2014, Integration of borehole and airborne transient electromagnetic data for automatic compilation of large scale hydrogeological models. Ph.D Thesis, Aarhus University.
He, X., Koch, J., Sonnenborg, T.O., Jargensen, F., Schamper, C., and Refsgaard, J.C., 2014, Uncertainties in constructing stochastic geological models using transition probability geostatistics and transient AEM 65 data: Water Resource Research, 50, 3147-3169.
Jargensen, F., Maller, R.R., Nebel, L., Jensen, N., Christiansen, A. V., and Sandersen, P., 2013, A method for cognitive 3D geological voxel modelling of AEM data: Bulletin of Engineering Geology and the Environment, 72, 34, 421-432.
Strebelle, S., 2002, Conditional simulation of complex geological structures using multiple-point statistics: Mathematical Geology, 34, 1, 1-21.
Sarensen, K.I. and Auken, E., 2004, SkyTEM - A new high-resolution helicopter transient electromagnetic system. Exploration Geophysics, 35, 191-199.

/content/journals/10.1071/ASEG2015ab256

Article Type: Research Article

Keyword(s): Airborne electromagnetic; Depth to bedrock; Geostatistical modelling; Geotechnical investigation; Interpolation

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oa Automated Airborne EM and borehole data integration for depth to bedrock extraction

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