Fracture Network Prediction Using Physics-based Machine Learning Algorithms Article Swipe

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Computer science Artificial intelligence Fracture (geology) Algorithm Machine learning Materials science Composite material

Abhash Kumar , William Harbert , Evgeniy M. Myshakin , Guoxiang Liu , Hema Siriwardane ·

YOU? · · 2024 · Open Access · · DOI: https://doi.org/10.2172/2426382 · OA: W4401437892

In recent years, systematic CO2 injection into geological reservoirs across the U.S. has gained traction as a strategy to mitigate greenhouse gas emissions. This approach necessitates precise monitoring to ensure secure containment, minimize risks, and optimize storage management. Our study leverages machine learning (ML) techniques to advance the understanding of CO2 injection processes, focusing on the Illinois Basin. Over a three-year injection period, we analyzed microseismic data, identifying 19 temporal intervals with significant bottom-hole pressure changes. By partitioning microseismic events into these intervals and estimating b-values, we revealed over 100 clusters of events related to fracture initiation or reactivation. Advanced spatial analysis highlighted horizontally-oriented fractures along the NNW-SSE axis. This quantification of fracture networks informs dynamic injection scheduling, work-over strategies, and risk assessments, enhancing carbon capture, utilization, and storage (CCUS) operations. Additionally, our methodology offers valuable insights for oil and gas operations and geothermal development, supporting fracture-based monitoring and risk mitigation.