3D modeling from outcrop data in a salt tectonic context: Example from the Inceyol minibasin, Sivas Basin, Turkey

Collon, Pauline; Pichat, Alexandre; Kergaravat, Charlie; Botella, Arnaud; Caumon, Guillaume; Ringenbach, Jean‐Claude; Callot, Jean‐Paul

doi:10.1190/int-2015-0178.1

Cited by 14 publications

(10 citation statements)

References 37 publications

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“…Heuristic approaches based on thickness considerations have been proposed to address this problem. (Caumon et al, 2013a;Collon-Drouaillet et al, 2015;Collon et al, 2016). Alternatively, in the case where enough data are available for the problem to be well posed, the increment of the scalar field can be estimated as differences to some reference value (Lajaunie et al, 1997;Chilès et al, 2004;Calcagno et al, 2008;De la Varga et al, 2018;Renaudeau et al, 2018).…”

Section: Full 3-d Modeling Approaches: Implicitmentioning

confidence: 99%

“…With these criteria in mind, we now highlight some distinctions between explicit and implicit models, summarized in Table 1. We also refer to Jessell et al (2014) and to Collon et al (2016) for comparisons and discussions of the relative merits of the various numerical approaches.…”

Section: Number Of Input Parametersmentioning

confidence: 99%

“…As compared to surface-based methods, interpolation can also change the topology of the implicit surfaces. This may be a strength when the topology is unknown (e.g., for karst or ore body modeling), but may also be a problem when the topology should be controlled (for instance to prevent stratigraphic surfaces to form blobs), see (Collon et al, 2016). Another capability of implicit methods is to honor several types of structural data without any projection (Calcagno et al, 2008;Caumon et al, 2013a;Hillier et al, 2014).…”

Section: Number Of Input Parametersmentioning

confidence: 99%

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3-D Structural geological models: Concepts, methods, and uncertainties

Wellmann

Caumon

2018

Advances in Geophysics

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178

103

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The Earth below ground is the subject of interest for many geophysical as well as geological investigations. Even though most practitioners would agree that all available information should be used in such an investigation, it is common practice that only a fraction of geological and geophysical information is used. We believe that some reasons for this omission are (a) an incomplete picture of available geological modeling methods, and (b) the problem of the perceived static picture of an inflexible geological representation in an image or geological model. With this work, we aim to contribute to the problem of subsurface interface detection through (a) the review of state-of-the-art geological modeling methods that allow the consideration of multiple aspects of geological realism in the form of observations, information and knowledge, cast in geometric representations of subsurface structures, and (b) concepts and methods to analyze, quantify, and communicate related uncertainties in these models. We introduce a formulation for geological model representation and interpolation and uncertainty analysis methods with the aim to clarify similarities and differences in the diverse set of approaches that developed in recent years. We hope that this chapter provides an entry point to recent developments in geological modeling methods, helps researchers in the field to better consider uncertainties, and supports the integration of geological observations and knowledge in geophysical interpretation, modeling and inverse approaches.

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Section: Full 3-d Modeling Approaches: Implicitmentioning

confidence: 99%

Section: Number Of Input Parametersmentioning

confidence: 99%

Section: Number Of Input Parametersmentioning

confidence: 99%

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3-D Structural geological models: Concepts, methods, and uncertainties

Wellmann

Caumon

2018

Advances in Geophysics

Self Cite

178

103

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“…Implicit surfaces also offer very nice ways to consider geometric model perturbations needed to address inverse problems in geosciences (Cardiff and Kitanidis 2009;Caumon et al 2007;Noetinger 2013;Zheglova et al 2013). A major distinction between explicit and implicit surface models is about topological control: the surface topology has to be chosen before interpolation in explicit methods, whereas it emerges from the interpolation in implicit models, see also Collon et al (2016) for more discussions.…”

Section: Geometry and Topologymentioning

confidence: 99%

Geological Objects and Physical Parameter Fields in the Subsurface: A Review

Caumon

2018

Handbook of Mathematical Geosciences

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Geologists and geophysicists often approach the study of the Earth using different and complementary perspectives. To simplify, geologists like to define and study objects and make hypotheses about their origin, whereas geophysicists often see the earth as a large, mostly unknown multivariate parameter field controlling complex physical processes. This chapter discusses some strategies to combine both approaches. In particular, I review some practical and theoretical frameworks associating petrophysical heterogeneities to the geometry and the history of geological objects. These frameworks open interesting perspectives to define prior parameter space in geophysical inverse problems, which can be consequential in under-constrained cases.

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“…These bodies have variable thicknesses, a wide range of shapes, and complex topologies with rare at depth constraints provided by sparse drillhole intercepts. Similar to working with salt bodies, these features prove difficult to model (Collon et al, 2016). Thicker accumulations of Moyie dikes, much more prevalent in Lower Aldridge turbidites, are imaged along the 2D seismic profiles (Cook and Van der Velden, 1995; Figure 11b), which provided anisotropy information and more textural information than discrete marker data used in modeling faults and horizons.…”

Section: D Regional-sparse Data Workflowmentioning

confidence: 99%

Assessing the workflow for regional-scale 3D geologic modeling: An example from the Sullivan time horizon, Purcell Anticlinorium East Kootenay region, southeastern British Columbia

et al. 2016

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We have developed a regional-scale 3D geologic model, highlighting the Mesoproterozoic Sullivan time horizon (approximately 1470 Ma) throughout the Purcell Anticlinorium in the East Kootenay region. This 3D geospatial model of the region is constrained with an extensive surface and subsurface database of stratigraphic, structural, and geophysical observations distributed throughout the study area. This modeling exercise was conducted over a four-year period from 2011 to 2015 in which several iterations of the model were produced. The final model includes what is locally referred to as the Lower-Middle Aldridge stratigraphic contact (LMC), a map unit at the very top of the lower Aldridge Formation where the Sullivan world-class Pb-Zn-Ag deposit is located. Local mineral exploration initiatives focus on this key exploration target horizon, which is now modeled in 3D. The regional LMC model provides a much needed geospatial reference used to characterize and understand sedimentary exhalative, a type of ore deposit (SEDEX) ore systems as well as a key 3D exploration target. Developing regional 3D geologic models for orogenic interiors such as the Purcell region, and older shield regions is a challenge. This is largely due to data sparsity at depth, lack of standards for 3D data collection, storage, integration, and interpretation practice. Current algorithms use only a partial set of available observational or knowledge constraints and exist in workflows that do not allow for complicated geologic event histories. We have mitigated some of these challenges with a new implicit algorithm (SURFE), applied in this Purcell case study, to estimate major regional faults and horizons through variably distributed and clustered data. These modeled geologic elements are then fed into the SKUA structural and stratigraphic workflow to produce the volumetric model. Reflection on the general 3D modeling workflow for these regional situations highlights the need for embedding more knowledge constraints into the process.

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3D modeling from outcrop data in a salt tectonic context: Example from the Inceyol minibasin, Sivas Basin, Turkey

Cited by 14 publications

References 37 publications

3-D Structural geological models: Concepts, methods, and uncertainties

3-D Structural geological models: Concepts, methods, and uncertainties

Geological Objects and Physical Parameter Fields in the Subsurface: A Review

Assessing the workflow for regional-scale 3D geologic modeling: An example from the Sullivan time horizon, Purcell Anticlinorium East Kootenay region, southeastern British Columbia

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