U-tube based near-surface environmental monitoring in the Shenhua carbon dioxide capture and storage (CCS) project

Self Cite

The risk potential matrix method can be used as a reference for the optimization of the traditional risk matrix in geological CO 2 storage. This study used monitoring data for environmentally sensitive receptors in the Jilin Oilfield CO 2 -enhanced oil recovery (CO 2 -EOR) Hei-79 block in conjunction with a hazard event store to create an updated risk assessment of CO 2 capture, use, and storage (CCUS) as a guide for risk management. The assessment built upon the overall project operation status to evaluate six and five sub-categories of hazard and sensitivity, respectively. The environmental sensitivity threshold integrated ecosystems and secondary geological disasters to amplify potential risks. The results of the risk assessment of the CO 2 -EOR Hei-79 block in the Jilin Oilfield showed that despite an overall risk level of Ⅱ, the hazard level resulted in an unacceptable increase in overall risk. Formations are usually stimulated by fracturing in Jilin Oilfield, particularly for oil and gas production.

Section: Identification Of Sensitive Receptorsmentioning

confidence: 99%

Risk assessment on the CCUS project using risk breakdown structure methodology: A case study on Jilin oilfield CO₂‐EOR Hei‐79 block

Wang

Liu

et al. 2021

Self Cite

“…CO 2 geological storage (CCS) is considered to be a crucial component of strategies to reduce atmospheric CO 2 emissions and a necessary means to achieve carbon neutrality. CCS plays a key role in addressing the urgent challenges of global warming, and significant results have been obtained in various large‐scale storage projects worldwide 1–3 . The principle of CCS involves capturing CO 2 that would have been emitted into the atmosphere, converting it into a supercritical state, and injecting it into the subsurface at suitable storage sites.…”

Section: Introductionmentioning

confidence: 99%

Two‐phase flow behavior in CO₂ geological storage considering spatial parameter heterogeneity

Zhong,

Li,

et al. 2023

Self Cite

Saline aquifer rocks exhibit significant spatial randomness due to geological sedimentation processes. To address the issue of the heterogeneity of rock formations in numerical simulations, it is common practice to homogenize rock layers with similar lithologies. However, the acceptability of the errors generated during homogenized computations is a major concern and should be investigated. Therefore, to study the influence of heterogeneity at the storage site on the CO2 migration behavior, the Monte Carlo simulation–random finite element method (MCS‐RFEM) was combined with a CO2 two‐phase flow model to compare the effects of the coefficient of variation (Cv) and correlation length (λx) of random reservoir permeability fields on the migration distance and extent of CO2 storage under the same mean conditions. The results showed that higher Cv and λx values significantly reduced the CO2 migration distance while increasing the spread extent. Compared to the homogeneous model, at a λx value of 100 m, the CO2 migration distance decreased by 5.05%, while the profile sweep area increased by 6.20%. Concurrently, with increasing Cv, the area with a CO2 volume fraction higher than 0.75 decreased by 20.22%, while an increase in λx resulted in a 42.35% increase in the area with a CO2 volume fraction higher than 0.75. Therefore, reservoirs with high Cv and low λx values are more suitable for safely storing CO2. © 2023 Society of Chemical Industry and John Wiley & Sons, Ltd.

Comprehensive review of experimental studies, numerical modeling, leakage risk assessment, monitoring, and control in geological storage of carbon dioxide: Implications for effective CO₂ deployment strategies

Sori,

Moghaddas,

Abedpour

2024

The geological storage of carbon dioxide (CO2) represents a promising strategy for mitigating climate change by securely sequestering CO2 emissions. This review article aims to provide a comprehensive overview of the current state of research and development in the field of geological carbon dioxide (CO2) sequestration. We systematically examined a wide range of recent literature, focusing on advancements in numerical simulations, experimental studies, risk assessments, and monitoring techniques related to CO2 sequestration. Literature was selected based on relevance, recency, and contribution to the understanding of key challenges and solutions in CO2 storage, with sources spanning peer‐reviewed journals, conference proceedings, and significant technical reports. Our review highlights several key themes: the integration of machine learning and advanced numerical models in predicting CO2 behavior in subsurface formations; innovative experimental approaches to understanding the physicochemical interactions between CO2, brine, and geological substrates; and the development of robust risk assessment frameworks to address potential leakage and induced seismicity. We also explore recent advancements in monitoring technologies, emphasizing their critical role in ensuring the long‐term integrity and effectiveness of CO2 storage sites. Overall, this review synthesizes the latest findings and identifies gaps in current knowledge, providing a roadmap for future research directions. Our aim is to enhance the understanding of CO2 sequestration processes, support the development of safer and more efficient storage methods, and contribute to the global effort in mitigating climate change through effective carbon management strategies. © 2024 Society of Chemical Industry and John Wiley & Sons, Ltd.