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New Insight of CO<sub>2</sub> Corrosion Performance on Cement for Enhanced Oil Recovery and Carbon Geological Storage Based on Nuclear Magnetic Resonance Technology

Daoyi Zhu, Qi Zhao, Jiong Zhang, Yingqi Gao, Guanhao Li, Zhongcheng Wu

2025Energy & Fuels13 citationsDOI

Abstract

As a major means of reducing carbon emissions and achieving the carbon-zero target, CO 2 geological storage has been widely applied in depleted oil or gas reservoirs for enhanced oil recovery. However, during CO 2 injection and long-term geological storage, the carbonation-induced corrosion of the cement sheath is the main threat as CO 2 may leakage from the well to atmosphere. In this study, G-grade oil well cement was placed in different CO 2 corrosion environments to investigate the effects of the CO 2 pressure and water saturation on long-term cement corrosion. Mechanical and pore permeability properties, as well as changes in the microstructure and composition, were analyzed using uniaxial compression, X-ray diffraction, mercury intrusion porosimetry, and scanning electron microscopy testing methods, respectively. Specially, nuclear magnetic resonance (NMR) technology was used to evaluate the pore changes in cement during the CO 2 corrosion. Results showed that wet-phase corrosion facilitated the occurrence of carbonation reactions and the migration of corrosive medium and products. Moreover, the microstructure and composition of the CO 2 -corroded cement exhibited different characteristics at different stages of corrosion. The T 2 spectrum curve indicated that the degree of CO 2 corrosion of cement was related to the diffusion rate of the CO 2 . When the pressure was low, CO 2 was difficult to penetrate deep into the cement, resulting in the smallest change in the NMR curve area under dry-phase CO 2 corrosion conditions at 5 MPa. This study employed nuclear magnetic technology to further analyze the mechanism of CO 2 corrosion on oil well cement at the microscopic level. It will contribute to a deeper understanding of the mechanism of CO 2 corrosion of cement and lay a theoretical analysis foundation for practical engineering applications of cement in CO 2 geological storage and enhanced oil recovery.

Topics & Concepts

CorrosionCementCarbon fibersCarbon capture and storage (timeline)Materials scienceNuclear magnetic resonanceMetallurgyComposite materialGeologyPhysicsClimate changeComposite numberOceanographyCO2 Sequestration and Geologic InteractionsDrilling and Well EngineeringEnhanced Oil Recovery Techniques