Abstract
Activated carbon beads, some of which contain Fe(3)O(4) nanoparticles or graphene oxide, were synthesized by thermal activation (700 °C) of chitosan hydrogel beads. Materials showed a multiporous scale (micro/meso/macro) and BET specific surface areas in the 260-572 m(2).g(-1) range. The adsorption kinetics of beads and powders resulting from their grinding were studied for a mixture of six micropollutants (bisphenol A, carbofuran, carbamazepine, diclofenac, dimethoate and imidacloprid) dissolved in spring water. While the adsorption kinetics on the beads (pH 7.3, 25 °C, 10-100 µg.L(-1)) are slow (equilibrium time > 24 h), the powdered samples are more efficient: for an initial concentration of 50 μg.L(-1) of each pollutant (0.1 g.L(-1) of adsorbent), 50 to 99% of the micropollutants introduced into the solution were removed after 4 h of contact time. Depending on the pollutant nature, the adsorption isotherms (0.2-40 μg.L(-1)) studied for an activated carbon powder containing Fe(3)O(4) (1 mass %) are either of Langmuir or Freundlich type, or they follow Henry's law and are related to the different properties of the molecules.