This paper examines the feasibility of combining a process known as enhanced methane recovery with partial coal pyrolysis to improve the petrophysics of coal seams and ultimately extract higher methane yields with accompanying pyrolysis gases. Partial pyrolysis for coal gas generation changes the pore and fracture structure, which in turn affect the permeability. A series of laboratory experiments on three coal rank samples monitored the changes in pore structure and permeability accompanying coal pyrolysis. Thermogravimetry-mass spectrometry (TG-MS) analysis evaluated mass loss and product composition. The pore and fracture structure evolution was determined by a combination of mercury intrusion porosimetry (MIP), scanning electron microscope (SEM) and methane adsorption capacity measurements on heat-treated coal blocks of similar to 100 g. The pore volume and methane adsorption capacity of LRC specimen (0.56% R-o,R-m) with 10 degrees C/min and a hold time of 30 min experienced slight changes during the heating process from 25 degrees C to 400 degrees C, but when heated from 400 degrees C to 800 degrees C, the pore volume in the LRC specimen greatly increased and the mercury-determined total porosity went from 36% at 400 degrees C to 43% at 800 degrees C. The permeability of the specimens at the temperature range of 300-400 degrees C increased exponentially with temperature due to the generated pore-fracture system. The sample LRC (800 degrees C) with the highest mercury-determined pore volume possessed the lowest methane capacity (19.45 cm(3)/g) due to the maximum adsorption volume of pyrolyzed coal obtained from the Langmuir model was related not only to the pore structure but also to the extent of graphitization. Therefore, they may have significant implications for enhanced coalbed methane (CBM) recovery. (c) 2014 Elsevier Ltd. All rights reserved.