Litcius/Paper detail

CO2 rock physics modeling for reliable monitoring of geologic carbon storage

Neala Creasy, Lianjie Huang, Erika Gasperikova, William Harbert, Tom Bratton, Quanlin Zhou

2024Communications Earth & Environment15 citationsDOIOpen Access PDF

Abstract

Abstract Monitoring, verification, and accounting (MVA) are crucial to ensure safe and long-term geologic carbon storage. Seismic monitoring is a key MVA technique that utilizes seismic data to infer elastic properties of CO 2 -saturated rocks. Reliable accounting of CO 2 in subsurface storage reservoirs and potential leakage zones requires an accurate rock physics model. However, the widely used CO 2 rock physics model based on the conventional Biot-Gassmann equation can substantially underestimate the influence of CO 2 saturation on seismic waves, leading to inaccurate accounting. We develop an accurate CO 2 rock physics model by accounting for both effects of the stress dependence of seismic velocities in porous rocks and CO 2 weakening on the rock framework. We validate our CO 2 rock physics model using the Kimberlina-1.2 model (a previously proposed geologic carbon storage site in California) and create time-lapse elastic property models with our new rock physics method. We compare the results with those obtained using the conventional Biot-Gassmann equation. Our innovative approach produces larger changes in elastic properties than the Biot-Gassmann results. Using our CO 2 rock physics model can replicate shear-wave speed reductions observed in the laboratory. Our rock physics model enhances the accuracy of time-lapse elastic-wave modeling and enables reliable CO 2 accounting using seismic monitoring.

Topics & Concepts

Biot numberShear wave splittingShear (geology)Saturation (graph theory)GeologyGeophysicsPhysicsPetrologyMechanicsMathematicsCombinatoricsSeismic Imaging and Inversion TechniquesCO2 Sequestration and Geologic InteractionsHydraulic Fracturing and Reservoir Analysis