Comparison of the adsorption of lead by activated carbons from three lignocellulosic precursors

Three activated carbons samples produced from Guava seeds, Tropical almond shells and Dinde stones were prepared by physical activation. The activated carbons have surface areas of around 1000 m(2) g(-1) and high micropore volumes of around 0.40 cm(3) g(-1). They were studied for the removal of lead from water in batch mode. Sorption studies were performed at different temperatures, initial pH, initial concentrations and adsorbent doses. Maximum adsorption occurred at pH 6 for an adsorbent dose of 0.5 g L-1. The sorption is favorable until an initial lead concentration of 90 mg L-1 for the activated carbons from Almond and Guava and only 25 mg L-1 for that of Dinole. The most favorable temperature is 30 degrees C for the activated carbons from Dinde and Almond with, 40 degrees C being favored by the one from Guava. The kinetic data were modelled with, the results showing that the Bangham model best describes the kinetics of the Almond and Dinde activated carbons and the Elovich model that of activated carbon from Guava seeds. Sorption equilibrium studies were conducted in a concentration range of lead from 0 to 230 mg L-1 and the isotherms were also modelled. The Khan equation gives the best fit for the sorption equilibrium data for the activated carbon from Almond, the Langmuir Freundlich equation for the one derived from Dinde and the Redlich-Peterson for the activated Guava seeds carbon. Finally, the thermokinetic parameters were evaluated. With a maximum amount of lead adsorbed as high as 50 (Dinde), 96 (Guava) and 112 mg g(-1) (Almond), these three activated carbons can be considered as efficient adsorbents for the remediation of lead from water. (C) 2015 Elsevier Inc. All rights reserved.