Investigation on the Methane Adsorption Capacity in Coals: Considerations from Nanopores by Multifractal Analysis

Methane adsorption properties of coal are essential for coalbed methane (CBM) extraction and clean energy utilization. However, the effect of nanopores on CH4 adsorption in high volatile bituminous coal and anthracite remains to be revealed. In this work, the multidimensional description of nanopores was established using gas adsorption and focused ion beam-scanning electron microscopy (FIB-SEM) experiments. The heterogeneous features at different sizes were finely quantified by multifractal analysis. Results show that the pores with size smaller than 100 nm, as storage section, are isolated in space. The nanopores of the sample LHG have stronger heterogeneity in multiple dimensions. The pore-size distributions with apparent aggregation are composed of 0.45-0.70 nm (from CO2 adsorption), 2-50 nm (from N-2 adsorption), and 10-50 nm (from FIB-SEM). The nanopore structure affects the adsorption capacity of CH4 mainly in the micropore structure, pore morphology, and heterogeneity. The well-developed micropore structure is conducive to methane enrichment. The narrow slit-like pores with the higher specific surface area are beneficial to gas storage, whereas nongrid aggregates of plate-like particles facilitate the desorption and diffusion of gas. The more robust pore heterogeneity in the range of 0.45-0.70 and 2-50 nm significantly contribute to methane adsorption. This work may allow significant insights into the interaction of coal with gases during enhancing CBM recovery.

Automated summary

This study established a multidimensional description of nanopores in high volatile bituminous coal and anthracite using gas adsorption and FIB-SEM experiments. The nanopore structure significantly affects the adsorption capacity of methane, mainly through micropore structure, pore morphology, and heterogeneity.