L-phenylalanine-assisted construction of hierarchically structured Fe(OH)3@Co2(OH)2CO3 with enhanced catalytic activities for the degradation of persistent organic pollutants

In this work, a flower-like Fe(OH)3@Co2(OH)2CO3 catalyst was prepared via the confinement effects provided by L-phenylalanine, which favored the heterostructure construction of active iron centers (Fe(OH)3) anchored on the Co2(OH)2CO3 nanosheet supports. Benefiting from the created electron-transfer interface and dual metal active sites, the limitation of redox cycling was broken and exhibited highly efficient catalytic activities, the optimal Fe(OH)3@Co2(OH)2CO3 catalyst showed comparable catalytic performance for the degradation of dye (degradation degree of 99% methylene blue and orange II within 18 min). In addition, the prepared catalysts were employed for the efficient removal of antibiotics (tetracycline (98.9%), norfloxacin (92.5%) and doxycycline hyclate (90.2%). Besides, the preferred nanofibrous composite membranes prepared by combination of nanofibrous membranes (NFMs) with Fe(OH)3@Co2(OH)2CO3 catalysts possessed considerable potential for large-scale MB removal (treatment capacity of 238.5 L m−2 and permeability of 191.8 L m−2 h−1 driven by gravity) and stability (182.7 L m−2 of treatment capacity was achieved in the third run). The strategy of construction of rapid interface-redox on the heterogenous catalysts was designed to enhance catalytic performance, which provided a promising chance for the efficiently large-scale removal of dyes and antibiotics.