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Towards geological inference with process-based and deep generative modeling, part 1: training on fluvial deposits

generative-ai › gans

📄 Abstract

Abstract: The distribution of resources in the subsurface is deeply linked to the variations of its physical properties. Generative modeling has long been used to predict those physical properties while quantifying the associated uncertainty. But current approaches struggle to properly reproduce geological structures, and fluvial deposits in particular, because of their continuity. This study explores whether a generative adversarial network (GAN) - a type of deep-learning algorithm for generative modeling - can be trained to reproduce fluvial deposits simulated by a process-based model - a more expensive model that mimics geological processes. An ablation study shows that developments from the deep-learning community to generate large 2D images are directly transferable to 3D images of fluvial deposits. Training remains stable, and the generated samples reproduce the non-stationarity and details of the deposits without mode collapse or pure memorization of the training data. Using a process-based model to generate those training data allows us to include valuable properties other than the usual physical properties. We show how the deposition time let us monitor and validate the performance of a GAN by checking that its samples honor the law of superposition. Our work joins a series of previous studies suggesting that GANs are more robust that given credit for, at least for training datasets targeting specific geological structures. Whether this robustness transfers to larger 3D images and multimodal datasets remains to be seen. Exploring how deep generative models can leverage geological principles like the law of superposition shows a lot of promise.

Authors (2)

Guillaume Rongier

Luk Peeters

Submitted

October 16, 2025

arXiv Category

cs.LG

arXiv PDF

Key Contributions

Demonstrates that Generative Adversarial Networks (GANs) can be trained to accurately reproduce complex fluvial deposits simulated by expensive process-based models. The study shows that standard 2D GAN advancements transfer to 3D, maintaining stable training, capturing non-stationarity and details without mode collapse, and offering a data-driven complement to process-based simulations.

Business Value

Improves the accuracy and efficiency of subsurface resource exploration and management by providing realistic geological models, potentially reducing exploration risks and costs.

Paper Metadata

Innovation Type

Application of AI to Scientific Domain

Deployment Feasibility

Moderate. Requires significant geological data and computational resources for training GANs.

Limitations Addressed

Current generative modeling approaches struggle to reproduce complex geological structures like fluvial deposits due to their continuity and non-stationarity.

Performance Gains

Successfully generates realistic 3D fluvial deposits, overcoming limitations of previous generative models in this domain.

Technical Tags

Generative Adversarial Networks (GANs)Process-based ModelingFluvial DepositsSubsurface CharacterizationGeological StructuresDeep Learning3D Image GenerationNon-stationarityAblation StudyMode CollapseResource Simulation

Research Topics

Geological ModelingGenerative AIDeep Learning for ScienceUncertainty QuantificationProcess Simulation

Methods & Architectures

Generative Adversarial Network (GAN)Process-based model simulationAblation study3D image generation Generative Adversarial Network (GAN)

Applications & Tasks

Geology Petroleum Engineering Geothermal Energy Carbon Sequestration Subsurface Resource Management Reproducing complex geological structures (fluvial deposits)Quantifying uncertainty in subsurface property predictionBridging the gap between process-based and data-driven modelsGenerating realistic 3D geological models Generating realistic fluvial depositsPredicting subsurface physical propertiesValidating GANs for geological applicationsAvoiding mode collapse and memorization

Related Fields

GeophysicsReservoir EngineeringComputer GraphicsScientific Machine Learning

Keywords

Generative Adversarial NetworksGANGeologyFluvial DepositsSubsurface ModelingDeep Learning3D GenerationProcess-based ModelingUncertainty QuantificationScientific AI

Academic Context

#Geological Modeling#Generative AI#Deep Learning for Science#Uncertainty Quantification#Process Simulation

Commercial Potential

Potential Products

Subsurface modeling softwareAI-driven exploration toolsGeological risk assessment platforms

Target Industries

Oil and GasMiningGeothermal EnergyEnvironmental EngineeringConstruction

Use Case Examples

Simulating reservoir heterogeneity for oil extractionPredicting groundwater flow pathsAssessing geological storage potential for CO2

Competitive Edge

Offers a data-driven approach using GANs that complements traditional process-based models, potentially providing more realistic and detailed geological structures.

Market Opportunity

Significant market in subsurface exploration and resource management.

Revenue Models

Licensing of AI models and softwareconsulting services.

Resource Requirements

Compute Needs

High (for GAN training)

Data Requirements

Simulated or real geological data (e.g., 3D seismic data, well logs, process-based simulation outputs).

Deployment Constraints

Need for large, high-quality geological datasets,Computational cost of training and inference

Scalability

Scalability depends on the GAN architecture and the complexity of the geological structures.

Regulatory Considerations

Potential use in environmental impact assessments and resource management regulations.

Production Readiness

Maturity Level

Research

Time to Market

3-6 years

Patent Potential

Moderate

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