Multifunctional alkali‐modified biochar‐nPd/Fe composites for enhanced removal of 2,4‐D: Preparation, characterization, and mechanism

Abstract

In this study, nPd/Fes were dispersed on peanut shells‐derived alkali‐modified biochar (BCalk) to obtain BCalk‐nPd/Fe composite for overcoming the instability, agglomeration, and oxidation of nPd/Fes. Results demonstrated that the dispersion stability and thermal stability of nPd/Fes were improved and the surface passivation layer was thinned by nanoparticles loading onto the alkalized biochar. Characterization analyses revealed of the improved 2,4‐D dichlorination by BCalk‐nPd/Fe. After biochar alkalization, more Si‐O‐Si sites on BCalk responsible for supporting nZVI particles were formed and coupled with nZVI to generate Si‐O‐Fe. Hence, nPd/Fes were immobilized on BCalk, while the increased oxygen‐containing surface functional groups promoted electron transport between nPd/Fes and 2,4‐D. Therefore, the BCalk‐nPd/Fe exhibited higher dechlorination efficiency toward 2,4‐D than that of nPd/Fe and BCraw‐nPd/Fe. About 99.25% and 89.11% of the 2,4‐D removal and dechlorination, respectively, were achieved after 150 min. Kinetic studies revealed that the removal of 2,4‐D using nPd/Fe, BCraw‐nPd/Fe, and BCalk‐nPd/Fe fitted well in the Langmuir–Hinshelwood kinetic model, and the order of rate constants was as follows: BCalk‐nPd/Fe > BCraw‐nPd/Fe > nPd/Fe. This study suggested that the prepared composites promoted detoxification and harmlessness of 2,4‐D contaminated wastewater and exhibited promising prospect in the efficient treatment of wastewater containing chlorinated organics.