Thermodynamical Studies of Irreversible Sorption of CO2 by Wyodak Coal

Abstract

<em>Differential scanning calorimetry (DSC), temperature programmed desorption mass spectrometry (TPD-MS) and small angle neutron scattering (SANS) were used to investigate CO₂ uptake by the Wyodak coal. Adsorption of carbon dioxide on Wyodak coal was studied by DSC. The exotherms evident at low temperatures are associated with the uptake of CO₂ suggesting that carbon dioxide interacts strongly with the coal surface. Reduction in the value of the exotherms between the first and second runs for the Wyodak coal suggests that some CO₂ is irreversibly bound to the structure even after heating to 200 °C. DSC results also showed that adsorption of CO₂ on the coal surface is an activated process and presumably at the temperature of the exotherms there is enough thermal energy to overcome the activation energy for adsorption. The adsorption process is instantly pursued by much slower diffusion of the gas molecules into the coal matrix (absorption). Structural rearrangement in coal by CO₂ is examined by change in the glass transition temperature of coal after CO₂ uptake at different pressures. The amount of gas dissolved in the coal increases with increasing CO₂ pressure. TPD-MS showed that CO₂ desorption from the Wyodak coal follows a first order kinetic model. Increase in the activation energy for desorption with pre-adsorbed CO₂ pressure suggests that higher pressures facilitate the transport of CO₂ molecules through the barriers therefore the amount of CO₂ uptake by the coal is greater at higher pressures and more attempts are required to desorb CO₂ molecules sorbed at elevated pressures. These conclusions were further confirmed by examining the Wyodak coal structure in high pressure CO₂ by SANS.</em>