Molecular simulation study on the influence of different temperatures and moisture contents on the adsorption characteristics of anthracite

The efficient development of coalbed methane (CBM) and CO₂ geological sequestration technologies plays a critical role in achieving a clean energy transition. However, the microscopic mechanisms underlying the effects of temperature and moisture on the adsorption characteristics of anthracite remain unclear. This study investigates the effects of temperature and moisture content on the adsorption characteristics of anthracite, using samples from the Yangquan mining region in Shanxi, China. A three-dimensional molecular model of anthracite was developed using the molecular dynamics (MD) simulation method. By contrasting the simulation outcomes with data from the CH₄ adsorption experiment, the reliability of the model was confirmed. The amount of adsorption, heat of adsorption, and diffusion coefficients of CO₂ and CH₄ in anthracite were examined using the Grand Canonical Ensemble Monte Carlo (GCMC) simulation method at temperatures between 293.15 and 333.15 K and moisture levels between 0 % and 3.20 %. The findings indicate that the simulated Langmuir volume for gas adsorption exceeds the experimental measurements, exhibiting a relative error of 4.3 %. Under varying temperatures and moisture contents, the gas adsorption isotherms followed the Langmuir type I model. The adsorption constants (a and b) are negatively correlated with the moisture content and temperature. At identical temperature and moisture content, the adsorption quantities of the two gases, heat of adsorption, and diffusion coefficient are related in the following way: CO₂ > CH₄. In dry circumstances, as the temperature rose, the diffusion coefficient rose, and the quantity and heat of gas adsorption on coal dropped. As the water content of coal increased, the quantity of gas that coal could adsorb and its diffusion coefficients decreased. However, adsorption heat increased with rising coal moisture content. This study provides a theoretical foundation for systematically understanding the adsorption characteristics of coalbed methane (CBM) on high-rank coal surfaces.