Alkali Activated Cedar Wood as an Efficient Adsorbent for Pb2+ Removal from Aqueous Solutions: Optimization, Kinetic and Thermodynamic Study

Abstract

In the present study, activated carbon prepared from cedar wood was synthesized, ‎via NaOH activation, and optimized to be used as the adsorbent for Pb2+ removal ‎from aqueous solutions in a batch process mode. The physicochemical properties ‎of the synthesized adsorbent were examined by SEM, FTIR and BET analysis. In ‎order to determine the optimum operational conditions, the effects of different ‎parameters including pH, adsorbent dosage, contact time, temperature, and initial ‎Pb2+concentration on the adsorptive performance of synthesized samples were also ‎investigated. According to the obtained results, the highest Pb2+ ion adsorption ‎capacity (971.9 mg/g) took place at the optimum operational condition of pH=4, ‎adsorbent dosage of 0.025 g/L, contact time of 60 minutes, 300 ppm of Pb2+ and ‎‎30 ℃. The results showed that among Langmuir, Freundlich, and Temkin ‎isotherms, the obtained data were fitted the best with the Freundlich model. ‎Additionally, the process of Pb2+ adsorption was consistent with the pseudo-‎second-order kinetics model, indicating that chemical adsorption was the dominant ‎mechanism of adsorption. Finally, according to the calculated thermodynamic ‎parameters, i.e., ∆H°, 〖∆S〗^° & 〖∆G〗^°, Pb2+ adsorption on activated cedar ‎wood can be considered as an exothermic and spontaneous process.‎