Chemistry, Physics and Technology of Surface

ISSN 2518-1238 (Online), ISSN 2079-1704 (Print)

The purpose of the work is to compare the adsorption of phenol (P) and 4-chlorophenol (CP) by activated carbons (ACs) from coals and coking semi-products (CSPs).

The ACs with specific surface S_DFT = 1009–1547 m²/g were prepared by alkaline activation at a KOH/substrate ratio of 1 g/g (800 °С, 1 h). The characteristics of ACs porosity were calculated by nitrogen adsorption – desorption isotherms (–196 °С). The adsorption capacities for P (А_P) and CP (А_CP) were measured at 25 °C, АC dosage – 1 g/l and concentration 5 mmol/l. The specific adsorption capacities (А_P(S), А_CP(S)) and the initial adsorption rates of P (V_P) and CP (V_CP) for the first 5 minutes of adsorption were also determined. The coal and CSP type were established to determine the porosity and adsorption activity of ACs. Adsorption kinetics obeys the pseudo-second order model (R² ≤ 0.996). The maximum capacities are A_P(m) = 1.52–3.11 mmol/g and A_CP(m) = 1.63–3.87 mmol/g. Initial rates are V_P = 0.096–0.258 mmol/g·min and V_CP = 0.107–0.607 mmol/g·min. With an S_DFT increase, the values of A_P(m) and A_CP(m) increase linearly. It was found that the specific capacities, which are proportional to the surface concentration of adsorption centers (AdCs), decrease linearly with the S_DFT growth for ACs from coals. The opposite trend was found for ACs from CSPs. All samples adsorb CP better than phenol in proportion of А_CP(S) = 1.455·А_P(S)–0.456 (R² = 0.944). The AdCs concentration increase was found to increase the CP specific adsorption rate. The opposite effect is observed for phenol – an AdCs concentration increase decreases the rate probably due to decreasing the energy of the interaction of P with AdCs. The ACs from low-rank coals were shown to be the most active adsorbents. The SPCs also improve adsorption properties, which makes promising their use for ACs preparation.

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