TY - JOUR
T1 - Simulation of CO2 Storage Using a Parameterization Method for Essential Trapping Physics
T2 - FluidFlower Benchmark Study
AU - Wang, Yuhang
AU - Zhang, Ziliang
AU - Vuik, Cornelis
AU - Hajibeygi, Hadi
PY - 2023
Y1 - 2023
N2 - An efficient compositional framework is developed for simulation of CO 2 storage in saline aquifers during a full-cycle injection, migration and post-migration processes. Essential trapping mechanisms, including structural, dissolution, and residual trapping, which operate at different time scales, are accurately captured in the presented unified framework. In particular, a parameterization method is proposed to efficiently describe the relevant physical processes. The proposed framework is validated by comparing the dynamics of gravity-induced convective transport with that reported in the literature. Results show good agreement for both the characteristics of descending fingers and the associated dissolution rate. The developed simulator is then applied to study the FluidFlower benchmark model. An experimental setup with heterogeneous geological layers is discretized into a two-dimensional computational domain where numerical simulation is performed. Impacts of hysteresis and the diffusion of CO 2 in liquid phase on the migration and trapping of CO 2 plume are investigated. Inclusion of the hysteresis effect does not affect plume migration in this benchmark model, whereas diffusion plays an important role in promoting convective mixing. This work casts a promising approach to predict the migration of the CO 2 plume, and to assess the amount of trapping from different mechanisms for long-term CO 2 storage.
AB - An efficient compositional framework is developed for simulation of CO 2 storage in saline aquifers during a full-cycle injection, migration and post-migration processes. Essential trapping mechanisms, including structural, dissolution, and residual trapping, which operate at different time scales, are accurately captured in the presented unified framework. In particular, a parameterization method is proposed to efficiently describe the relevant physical processes. The proposed framework is validated by comparing the dynamics of gravity-induced convective transport with that reported in the literature. Results show good agreement for both the characteristics of descending fingers and the associated dissolution rate. The developed simulator is then applied to study the FluidFlower benchmark model. An experimental setup with heterogeneous geological layers is discretized into a two-dimensional computational domain where numerical simulation is performed. Impacts of hysteresis and the diffusion of CO 2 in liquid phase on the migration and trapping of CO 2 plume are investigated. Inclusion of the hysteresis effect does not affect plume migration in this benchmark model, whereas diffusion plays an important role in promoting convective mixing. This work casts a promising approach to predict the migration of the CO 2 plume, and to assess the amount of trapping from different mechanisms for long-term CO 2 storage.
KW - Compositional simulation
KW - Convective mixing
KW - Geological CO storage
KW - Hysteresis
KW - Porous media
UR - http://www.scopus.com/inward/record.url?scp=85164512266&partnerID=8YFLogxK
U2 - 10.1007/s11242-023-01987-5
DO - 10.1007/s11242-023-01987-5
M3 - Article
AN - SCOPUS:85164512266
SN - 0169-3913
VL - 151
SP - 1053
EP - 1070
JO - Transport in Porous Media
JF - Transport in Porous Media
IS - 5
ER -