TY - JOUR
T1 - Bubble Coarsening Kinetics in Porous Media
AU - Yu, Yuehongjiang
AU - Wang, Chuanxi
AU - Liu, Junning
AU - Mao, Sheng
AU - Mehmani, Yashar
AU - Xu, Ke
N1 - Funding Information:
We gratefully acknowledge the financial support and funding provided by the National Key Research and Development Program of China under Grant 2021YFA0717200, by the National Natural Science Foundation of China under Grant 12172010, and by the CNPC Research Institute of Petroleum Exploration and Development for the project “Key Fluid Mechanisms of CO2-EOR for Gu-Long Shale Oil Development.” Yashar Mehmani acknowledges the Department of Energy and Mineral Engineering (EME) and the College of Earth and Mineral Sciences (EMS) for providing the funds for this project. The authors thank Dr. Sally Benson for helpful discussions during AGU2019 conference.
Funding Information:
We gratefully acknowledge the financial support and funding provided by the National Key Research and Development Program of China under Grant 2021YFA0717200, by the National Natural Science Foundation of China under Grant 12172010, and by the CNPC Research Institute of Petroleum Exploration and Development for the project “Key Fluid Mechanisms of CO‐EOR for Gu‐Long Shale Oil Development.” Yashar Mehmani acknowledges the Department of Energy and Mineral Engineering (EME) and the College of Earth and Mineral Sciences (EMS) for providing the funds for this project. The authors thank Dr. Sally Benson for helpful discussions during AGU2019 conference. 2
Publisher Copyright:
© 2022. The Authors.
PY - 2023/1/16
Y1 - 2023/1/16
N2 - Bubbles in subsurface porous media spontaneously coarsen to reduce free energy. Bubble coarsening dramatically changes surface area and pore occupancy, which affect the hydraulic conductivity, mass and heat transfer coefficients, and chemical reactions. Coarsening kinetics in porous media is thus critical in modeling geologic CO2 sequestration, hydrogen subsurface storage, hydrate reservoir recovery, and other relevant geophysical problems. We show that bubble coarsening kinetics in porous media fundamentally deviates from classical Lifshitz-Slyozov-Wagner theory, because porous structure quantizes the space and rescales the mass transfer coefficient. We develop a new coarsening theory that agrees well with numerical simulations. We identify a pseudo-equilibrium time proportional to the cubic of pore size. In a typical CO2 sequestration scenario, local equilibrium can be achieved in 1s for media consisting of sub-micron pores, while in decades for media consisting of 1 mm pores. This work provides new insights in modeling complex fluid behaviors in subsurface environment.
AB - Bubbles in subsurface porous media spontaneously coarsen to reduce free energy. Bubble coarsening dramatically changes surface area and pore occupancy, which affect the hydraulic conductivity, mass and heat transfer coefficients, and chemical reactions. Coarsening kinetics in porous media is thus critical in modeling geologic CO2 sequestration, hydrogen subsurface storage, hydrate reservoir recovery, and other relevant geophysical problems. We show that bubble coarsening kinetics in porous media fundamentally deviates from classical Lifshitz-Slyozov-Wagner theory, because porous structure quantizes the space and rescales the mass transfer coefficient. We develop a new coarsening theory that agrees well with numerical simulations. We identify a pseudo-equilibrium time proportional to the cubic of pore size. In a typical CO2 sequestration scenario, local equilibrium can be achieved in 1s for media consisting of sub-micron pores, while in decades for media consisting of 1 mm pores. This work provides new insights in modeling complex fluid behaviors in subsurface environment.
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U2 - 10.1029/2022GL100757
DO - 10.1029/2022GL100757
M3 - Article
AN - SCOPUS:85146051131
SN - 0094-8276
VL - 50
JO - Geophysical Research Letters
JF - Geophysical Research Letters
IS - 1
M1 - e2022GL100757
ER -