Speaker: Amandine Fratani
Date: Thursday 26th of June 2025, 1:15pm
Abstract:
The construction of geological models in sedimentary basins is largely constrained by the interpretation of faults and horizons in seismic and drillhole data and by associating observations into distinct entities (e.g., forming a single fault or one horizon). Due to the sparsity and incompleteness of data, several fault networks can usually be drawn from a given set of observations. This problem has been considered using graph formalism with nodes carrying the fault observation and the edges carrying information on the potential that they are associated. This potential has previously been proposed to be computed using machine learning, specifically the application of a Random Forest. However, the lack of open access structural models limits the use of machine learning. Therefore, this methodology has only been tested on partially interpreted cases. To generalise the approach, this work presents a database under development comprising synthetic structural models featuring normal faults. A random geological history and model generation code, Noddy, has been modified to include more realistic fault events. Faults are grouped into families where fault from a family have similar orientation for fault surfaces. Each family is defined as a mean dip and a mean dip direction, select randomly. A fault orientation is defined by sampling a Kent distribution centred on the dip and dip direction of the family to which it belongs. The resulting geological models are imported into geological modelling software where the surfaces are smoothed. Fault observations are then sampled in these models and will be used to train a Random Forest to retrieve the potential associations.
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- Category: Seminar
Speaker: Mohamed Sherif Mahrous
Date: Thursday 19th of June 2025, 1:15pm
Abstract:
A significant production of hydrogen is expected inside geological nuclear waste repository. The gaseous phase is foreseen to modify the flows and mechanical conditions of the rock and engineered material. As a part of EURAD 2 project (2024-2028), this work plans to implement the coupling between the different physical (THMC) processes involved in gas migration and to upscale results into the continuum scale. Towards this end, a pore scale Hydro-Mechanical-gas code has been developed in EURAD1 project, based on Smoothed Particle Hydrodynamics, to study water-gas migration accounting for drying within a deformable solid (elastic with thermodynamical damage model). The main objectives of this work are:
1. Apply the THMC couplings in the near- and far-field at the micro and meso scale (order of tens of pores) in the already existing SPH code.
2. Investigate the temperature dependency of multiphase flow parameters.
3. Compute effective properties (e.g., saturation curve, relative permeability, poromechanical properties).
4. Explore the consequences of usual simplifications.
5. Provide benchmarking and training data for predictive surrogate models.
6. Deliver results for code comparisons and experimental benchmarking.
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- Category: Seminar
Speaker: Loïs Letellier
Date: Thursday 10th of April 2025, 1:15pm.
Abstract:
Well log interpretation is a time consuming task, which, moreover, depends on the interpreter's experience, as there exists different admissible interpretations for a same input log. To account for the uncertainty of the interpretation, we propose to use a signal processing technique, the Continuous Wavelet Transform (CWT), that gives information on the signal considering both depth and scale parameters. The result of this transform is then processed to extract some features of the signal (i.e. the local extrema of the signal at different scales), and propose different geological scenarios. We then compare the different solutions with experts' interpretations.
These different scenarios are destined to be included in a correlation process, in order to study correlations with a multi-scale approach, which allows to explore the range of possibilities, while reducing the computational cost using a hierarchical process.
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- Category: Seminar
Speaker: Imadeddine Laouici
Date: Thursday 12th of June 2025, 1:15pm.
Abstract:
Building structural models of geological entities is generally addressed as an interpolation problem that requires human experts to interpret input data and use knowledge (Wellmann and Caumon, 2018). Although experts can effectively interpret, their interpretations can be subjective and occasionally prone to error (Bond, 2015). This is largely due to under-sampling of data, requiring experts to make choices in the selection and preparation of these data and knowledge (Bond et al., 2012), and selection and configuration of modeling algorithms (Caumon et al., 2009). Modeling algorithms also do not reflect the complex expert interpretation process, as they incorporate only a portion of the knowledge typically held by experts and have limited ability to directly interact with experts during the interpretation process itself. This makes it challenging to build geologically complex models and systematically identify and address inconsistencies in a model. A crucial step toward resolving these issues is the formalization of the interpretation process and the explicit use of formalized knowledge. In this work we develop and prototype such a formalization. A prototype algorithm and tool (Figure 1) are presented and applied to simple folding structures, and the results are favorably compared to existing approaches. This comparison highlights the potential of the proposed approach to reduce the need for expert involvement and increase the range of knowledge utilized.
Bond, C.E., 2015. Uncertainty in structural interpretation: Lessons to be learnt. Journal of Structural Geology 74, 185–200. https://doi.org/10.1016/j.jsg.2015.03.003
Bond, C.E., Lunn, R.J., Shipton, Z.K., Lunn, A.D., 2012. What makes an expert effective at interpreting seismic images? Geology 40, 75–78. https://doi.org/10.1130/G32375.1
Caumon, G., Collon-Drouaillet, P., Le Carlier de Veslud, C., Viseur, S., Sausse, J., 2009. Surface-Based 3D Modeling of Geological Structures. Math Geosci 41, 927–945. https://doi.org/10.1007/s11004-009-9244-2
Wellmann, F., Caumon, G., 2018. 3-D Structural geological models: Concepts, methods, and uncertainties. Advances in Geophysics 59, 1–121. https://doi.org/10.1016/bs.agph.2018.09.001
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- Category: Seminar
Speaker: Mike Heap
Date: Thursday 27th of March 2025, 1:15pm.
Abstract:
Hydrothermal alteration describes a process that progressively, and additively, modifies the chemical, physical, mechanical, and transport properties of rock by fluid-rock interactions. At active volcanoes, mixtures of magmatic and meteoric fluids circulate within the rocks forming the volcano and, as a result, hydrothermal alteration can be pervasive. Because the properties of volcanic rocks and rock-masses, such as their strength or their permeability, play a role in dictating the hazard potential of a volcano, then it follows that hydrothermal alteration can progressively modify the hazard potential of a volcano. However, not only does subsurface hydrothermal alteration proceed largely imperceptibly, leading to unpredictable hydrothermal explosions and mass wasting events, but we also do not fully understand the timescales required for hydrothermal alteration, nor its influence of rock properties. As a result, and despite its potential importance, hydrothermal alteration is not routinely monitored at active volcanoes, and often does not feature in routine volcanic hazard assessments. In this seminar, I will outline recent, multidisciplinary advancements in our understanding of hydrothermal alteration, and its influence on volcanic hazards.
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- Category: Seminar
Speaker: Jeremie Giraud
Date: Thursday 15th of May 2025, 11am.
Abstract:
We present and apply a pseudo trans-dimensional inversion method for 3D geometrical gravity inversion, in which the number of rock units, their geometry, and their density can vary during sampling. The method builds on a multiple level set framework and uses a birth-death process to insert or remove rock units from an existing model. Interface geometries are perturbed using random fields, and densities are sampled from distributions informed by prior geological knowledge. Sampling is performed using a non-reversible Metropolis-Hastings algorithm designed to efficiently explore complex model spaces while ensuring a parsimonious solution.
The method is applied to gravity data from the prospective Boulia region (Queensland, Australia) to image rocks beneath sedimentary cover. In this field case, an implicit geological model—constructed from the interpretation of 2D seismic lines, borehole data, and geological rules—is used to define prior geological constraints on the inversion. To aid interpretation, a workflow combining dimensionality reduction and clustering is applied to the ensemble of sampled models, allowing identification of families of geologically plausible solutions. Preliminary results suggest that up to two dense rock units, not initially identified by the geological model, may be needed to explain the observed data. Overall, our analysis of results suggests the ability of the method to infer the presence of previously unrecognized geological features, such as buried intrusions or facies variations, and indicates its potential as a tool to support exploration.
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- Category: Seminar