Preparation of magnetic N-doped iron sludge based biochar and its potential for persulfate activation and tetracycline degradation

The widespread use of tetracycline (TC) is a non-negligible cause of environmental pollution, such as antibiotic resistance genes (ARGs). Economical, green and efficient treatment methods are urgently needed. In this study, the magnetic N-doped iron sludge based biochar (N-BCFe) was prepared by a one-step pyrolysis method using the iron-containing sludge from groundwater treatment plants, sycamore leaves and urea as raw materials to active persulfate (PS) for TC degradation. The results show that under the optimal experimental conditions, the removal rate of 10 mg/L TC in the N-BCFe/PS system could reach 86.56% (120 min), accompanied by a 59.9% reduction in total organic carbon (TOC), and still 63.34% of TC was removed in the third recycle experiment. Combined with EPR, free radical quenching experiments and XPS spectra, it is confirmed that there are free radicals (SO4 center dot-,(OH)-O-center dot) and non-radical (O-1(2)) pathways in N-BCFe/PS system. And the former is related to Fe doping, while the latter is attributed to N doping (nitrogen-containing functional groups). Seventeen TC intermediates were identified by LC-MS technology, and three TC degradation pathways were established accordingly. Generally, this study illustrates the considerable catalytic potential of N-BCFe and provides valuable insights into the synthesis of catalysts prepared from iron-containing sludge as feedstock.

Automated summary

This study investigates the catalytic potential of magnetic N-doped iron sludge based biochar (N-BCFe) for tetracycline (TC) degradation. The results demonstrate the significant removal efficiency of TC in the N-BCFe/PS system and reveal the reaction mechanism and degradation pathways involved. The study provides valuable insights into the synthesis of catalysts from iron-containing sludge and their application in environmental remediation.