Influences of Evolution of Pore Structures in Tectonic Coal under Acidization on Methane Desorption

[Image: see text] Experiments on corrosion reactions of pulverized coal with monomeric and polymeric (mixed) acid solutions reveal that monomeric acids are listed in a descending order as HF, HCl, and CH(3)COOH according to their corrosion effects on tectonic coal collected in Faer Coal Mine (Liupanshui City, Guizhou Province, China). In addition, the optimal mixing ratio of mixed acids is 6% HCl + 6% HF + 3% CH(3)COOH + 2% KCl. The mineral grains filled in pores in coal samples treated with mixed acid solutions are dissolved, so the porosity increases. The volumes of transition pores and mesopores are obviously affected by acidization, and some transition pores are transformed into mesopores and macropores to form dissolved pores. At the same time, inkbottle-shaped pores reduce, while slit pores or open pores increase. The coal samples after acidization show a higher aromatization degree and an increased relative content of oxygen-containing functional groups, with a generally lower hydroxyl content, so the methane (CH(4)) adsorption capacity of coal declines, which promotes CH(4) desorption. The control effect of pore structures after acidization reactions on CH(4) desorption was revealed from perspectives of the diffusion coefficient (Kn), adsorption volume (ω), average pore–throat ratio (P(T)), and average sinuosity (τ(av)). That is, CH(4) molecules in tectonic coal after acidization turn from Knudsen diffusion to transitional diffusion, the adsorption volume of CH(4) molecules shrinks, the average pore–throat ratio decreases, and the average sinuosity reduces, which promotes CH(4) desorption from tectonic coal.