3D geologic subsurface modeling within the Mackenzie Plain, Northwest Territories, Canada

Three-dimensional (3D) models are widely used within the geosciences to provide scientists with conceptual and quantitative models of the earth’s subsurface. As a result, 3D geologic modelling is a growing field, such that scientific research often cannot keep up with technical advancements. Literat...

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Bibliographic Details
Main Author: Raska, Nadine
Format: Other/Unknown Material
Language:English
Published: Lunds universitet/Institutionen för naturgeografi och ekosystemvetenskap 2017
Subjects:
geology
3D modeling
geography
geographic information systems
horizons
stratigraphic modeling
Earth and Environmental Sciences
Northwest Territories
Canada
Online Access:http://lup.lub.lu.se/student-papers/record/8902243
Description
Summary:Three-dimensional (3D) models are widely used within the geosciences to provide scientists with conceptual and quantitative models of the earth’s subsurface. As a result, 3D geologic modelling is a growing field, such that scientific research often cannot keep up with technical advancements. Literature often shows conflicting results with respect to which interpolation algorithms produce the best surfaces, and it is not always clear which methods are most appropriate for a particular geological setting. This study looks at three commonly used interpolation techniques – Inverse Distance Weighting (IDW), kriging and triangulation – and assesses their effectiveness at capturing geologic structures in the subsurface. The study uses a modified Horizons method to create a solid 3D stratigraphic model of the subsurface of an area within the Mackenzie Plain, NWT, in Canada. The Horizons method involves interpolating individual stratigraphic surfaces, or horizons, representing their depositional sequence. Surface intersections are corrected where necessary, and a solid model is built by extruding each surface down to the top of the surface below. Triangulation produced the most geologically appropriate surfaces, whereas IDW produced surfaces with a stronger bullseye effect; although kriging produced some surfaces well, it did not result in acceptable surfaces where discontinuities were present. Structural features such as folds in the subsurface were captured only where the data density was sufficient. Large folds spanning the majority of the study area were visible in the modelled surfaces; however smaller folds and monoclines were not visible. It was possible to model a thrust fault in the subsurface by creating two separate stratigraphic models on either side of the fault, cutting them at the fault plane and merging them together after each side was converted to a solid model. The model produced in this study showed promise as a basis for future modelling and further 3D model refinements. The modelling process was ...

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