CO2 trapping dynamics in tight sandstone: Insights into trapping mechanisms in Mae Moh's reservoir

• Published in: Journal of environmental management Vol. 370; p. 122442
• Main Authors: Ramadhan, Romal, Tapanya, Chetsada, Akamine, Thakheru, Leelasukseree, Cheowchan, Tangparitkul, Suparit
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.11.2024
• Subjects: Carbon geological storage; CO2 trapping mechanism; Reservoir simulation; Tight sandstone; CO2 trapping mechanism; Tight sandstone; Carbon geological storage; Reservoir simulation
• ISSN: 0301-4797; 1095-8630; 1095-8630
• DOI: 10.1016/j.jenvman.2024.122442

The reliance on fossil fuels is a major contributor to increased anthropogenic CO2 emissions, driving global challenges such as climate change through the greenhouse effect. Carbon capture and storage (CCS) is a promising interdisciplinary technology aimed at mitigating these emissions by securely sequestering gigatons of CO2. This study focuses on the feasibility of storing point-source CO2 emissions in saline formations, with a particular emphasis on the Mae Moh coal-fired power plant in Lampang, Thailand, which is located near its associated coal mine. The region presents challenges due to tight sandstone reservoirs buried over 2000 m deep. With reservoir simulation, this study evaluates the impact of various factors on CO2 containment and trapping in these geological settings. Results show that elevated temperatures decrease structural trapping of 43.0%–28.9% and increase solubility trapping of 28.55%–46.5%, at 40 °C and 80 °C respectively. Hysteresis is found to enhance residual trapping by immobilizing up to 31.1% of CO2 within pore spaces at 0.5. Permeability heterogeneity has a minimal impact on overall trapping efficiency due to the less heterogeneity of the tight sandstone. However, the kV/kH ratio significantly influences vertical CO2 migration which resulted in residual trapping at its highest at the ratio of 0.1, while lower ratios support lateral dispersion. Moderate rock compressibility values are identified as optimal for structural and residual trapping, while extreme compressibility enhances solubility trapping by up to 30%. These findings emphasize the complexity of CO2 trapping mechanisms in tight sandstone formations, emphasizing the need for careful consideration of key factors in CCS projects. •A tight sandstone formation was investigated for its potential to store CO2.•The combined effects of temperature, hysteresis, pressure, permeability, kV/kH ratio, and compressibility were evaluated.•Influencing factors on storage containment and trapping mechanisms were identified.