Influence of Supercritical CO₂ Fluid on CH₄ and CO₂ Diffusion in Vitrinite-Rich Coals and Inertinite-Rich Coals

Coal maceral composition has a great effect on gas adsorption and diffusion. The interaction between maceral composition and supercritical CO₂ (SCCO₂) fluid will affect gas diffusion behavior in coals. Thus, the diffusivity derived from adsorption kinetics of CH₄ and CO₂ in vitrinite- and inertinite-rich coals with low-violate bituminous rank collected from the Hancheng mine of the Weibei coalfield pre- and post-SCCO₂ fluid exposure (SFE) were tested at the conditions of 45 °C and 0.9 MPa. In combination with pore distribution and functional group content, the possible mechanism of the alterations in gas diffusion characteristics in coals with various maceral compositions was addressed. The results show that for vitrinite-rich coals, SFE increases the macropore apparent diffusion coefficient of CH₄, while this treatment decreases the micropore apparent diffusion coefficient of CH₄. However, the reverse trend is found for CO₂ diffusion–adsorption rate. For inertinite-rich coals post-SFE, CH₄ diffusion–adsorption rate increases, while an increase and a decrease in diffusivity CO₂ occur for macropore and micropore, respectively. Generally, SFE shows a stronger impact on CO₂ adsorption rate than CH₄ in coals. The results suggest that the diffusion of CH₄ and CO₂ in coals with different maceral compositions show selectivity to SCCO₂ fluid. The possible reason can be attributed to the changes in pore structure and surface functional group content. SFE causes an increase in macro/mesopore volume of all samples. However, SFE induces a reduction in oxygen-containing species content and micropore volume of inertinite-rich coals, while the opposite trend occurs in vitrinite-rich coals. Thus, the changes in pore volume and surface functional group account for the difference in gas diffusivity of coals with different maceral compositions. With regard to the micropore diffusion–adsorption behavior of CH₄ and CO₂, the impact of oxygen-containing species is superior to pore volume. The oxygen-containing species favor CO₂ diffusion–adsorption but go against CH₄ transport. This effect accounts for the reduction in the micropore diffusion–adsorption rate of CH₄ and the increase in micropore diffusivity of CO₂ in vitrinite-rich coals, respectively. However, the aforementioned effect is the opposite for inertinite-rich coals. Overall, the changes in gas diffusion in coals with different maceral composition during the CO₂-ECBM process requires further attention.