The impact of supercritical CO2 on the pore structure and storage capacity of shales

• Published in: Journal of natural gas science and engineering Vol. 98; p. 104394
• Main Authors: Fatah, Ahmed, Ben Mahmud, Hisham, Bennour, Ziad, Gholami, Raoof, Hossain, Mofazzal
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.02.2022
• Subjects: CO2 sequestration; Geological storage; Mineral composition; Pore structure; Shales; CO2 sequestration; Geological storage; Mineral composition; Pore structure; Shales
• ISSN: 1875-5100
• DOI: 10.1016/j.jngse.2021.104394

Injection of supercritical CO2 (SCCO2) causes significant changes in the petrophysical properties of shales and affects the integrity of geological storage sites. The alteration of mineralogy and pore structure plays a major role in defining the fluid transport in pours media of shale gas during CO2 storage. In this study, a series of SCCO2 treatment experiments were performed on different types of shales to evaluate the alterations of the pore structure and mineralogy. Two types of shales from Eagle Ford and Mancos fields were treated with SCCO2 and analyzed with scanning electron microscope, X-ray diffraction, and low-pressure nitrogen adsorption before and after 30 days at 70 °C and 18 MPa. The experimental results indicated that SCCO2 affected the mineral composition and changed the macropore structure of shales, due to the adsorption-induced expansion effect. The pore structure of clay-rich shales samples was more affected by CO2 treatment compared to quartz-rich shales, due to the dissolution of clay contents in the former, which reduced the overall pore volume by 24% in Eagle Ford shales. Conversely, the development of micro-cracks in Mancos shale surface created new pores and increased the pore volume by more than 13%. The results from nitrogen adsorption isotherms indicated a prominent alteration in the mesopores structure. The specific surface area and total pore volume of Eagle Ford shale reduced by 35.46% and 11.86% respectively after the SCCO2 treatment, while the specific surface area and total pore volume of Mancos shale increased by 27.4% and 25.92% respectively. A positive correlation was reported between the fractal dimension and specific surface area. It appeared that the surface roughness was reduced in Eagle Ford shale and relatively increased in Mancos shales after the treatment. The obtained results suggested that the adsorption capacity of clay-rich shales could be reduced after the CO2 treatment, while quartz-rich shales displayed a uniformed pore size distribution profile, indicating a possible increase in the adsorption capacity. These findings can provide technical support to further understand the effect of CO2 on the pore structure and mineralogical alteration of shale during geological storage. •The pore structure of clay-rich shales was more affected by CO2 treatment compared to quartz-rich shales.•The adsorption capacity of clay-rich shales could be reduced after the CO2 treatment.•Quartz-rich shales displayed a uniformed pore size distribution profile, indicating an increase in the adsorption capacity.•A positive linear correlation was reported between fractal dimensions and Specific Surface Area for shales.•Shale mineralogy has a key role in evaluating fluid transport in pores during of shale gas development and CO2 storage.