posted on 2021-03-18, 16:38authored byJunyoung Hwang, Ronny Pini
Understanding
the long-term confinement of supercritical fluids
in the clay pores of subsurface rocks is important for many geo-energy
technologies, including geological CO2 storage. However,
the adsorption properties of hydrated clay minerals remain largely
uncertain because competitive adsorption experiments of supercritical
fluids in the presence of water are difficult. Here, we report on
the sorption properties of four source clay mineralsCa-rich
montmorillonite (STx-1b), Na-rich montmorillonite (SWy-2), illite–smectite
mixed layer (ISCz-1), and illite (IMt-2)for water at 20 °C
up to relative humidity of 0.9. The measurements unveil the unsuitability
of physisorption analysis by N2 (at 77 K) and Ar (at 87
K) gases to quantify the textural properties of clays because of their
inability to probe the interlayers. We further measure the sorption
of CO2 and CH4 on swelling STx-1b and nonswelling
IMt-2, both in the absence (dehydrated at 200 °C) and the presence
of sub-1W preadsorbed water (following dehydration) up to 170 bar
at 50 °C. We observe enhanced sorption of CO2 and
CH4 in STx-1b (50 and 65% increase at 30 bar relative to
dry STx-1b, respectively), while their adsorption on IMt-2 remains
unchanged, indicating the absence of competition with water. By describing
the supercritical adsorption isotherms on hydrated STx-1b with the
lattice density functional theory model, we estimate that the pore
volume has expanded by approximately 6% through the formation of sub-nanometer
pore space. By presenting a systematic approach of quantifying the
smectite clay mineral’s hydrated state, this study provides
an explanation for the conflicting literature observations of gas
uptake capacities in the presence of water.