Introduction
•Many pieces of research have been established to develop a good modelling approach that can analyze and simulate the carbon dioxide injection process (in supercritical and gas phase). However, little research has been done on a fully coupled relationship. The mixture coupling theory approach developed to capture fluid transport in deformable porous media is a good base for developing such a model. A fully coupled Thermo-Hydro-Mechanical-Gas-Chemical (THMGC) model based on the mixture coupling theory approach is developed in this research. The model should be able to simulate the carbon dioxide injection process in a deep formation with reasonable accuracy. The model shall capture complex coupled processes, including dissolution/ precipitation chemical processes.
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Related research can be divided into:
Part 1. The environmental impacts of carbon geological storage: THMC modelling
Part 1. The environmental impacts of carbon geological storage: THMC modelling
Mr Sulaiman Abdullah
Many pieces of research have been established to develop a good modelling approach that can analyze and simulate the carbon dioxide injection process (in supercritical and gas phase). However, little research has been done on a fully coupled relationship. The mixture coupling theory approach developed to capture fluid transport in deformable porous media is a good base for developing such a model. A fully coupled Thermo-Hydro-Mechanical-Gas-Chemical (THMGC) model based on the mixture coupling theory approach is developed in this research. The model should be able to simulate the carbon dioxide injection process in a deep formation with reasonable accuracy. The model shall capture complex coupled processes, including dissolution/ precipitation chemical processes.
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Related publications
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Abdullah Sulaiman, Ma Yue, Chen Xiaohui, and Khan Amirul. A Fully Coupled Hydro-Mechanical-Gas Model Based on Mixture Coupling Theory[J]. Transport in porous media, 2022: 1-22.
