Using red mud from alumina industry waste and edible fungus industry waste fungus rod as raw materials, red mud/waste fungus magnetic biochar (RMMBC) was prepared by co-pyrolysis method, and its morphological characteristics, pore structure and surface functional group changes were analyzed, its adsorption effect on norfloxacin(NOR) in water was explored, and its adsorption mechanism was explored by adsorption kinetics and isothermal adsorption characteristics, and tested in actual wastewater. The results showed that the optimal preparation conditions were raw material ratio (red mud, waste bacterial residue, urea) 1: 2.5: 0.5, calcination time 1 h, calcination temperature 700 °C. The maximum removal rate of NOR was 96.3% when a NOR concentration was 10 mg/L and 0.25 g RMMBC was added. The results showed that RMMBC had a large specific surface area(59.295 m²/g), pore volume (20.157 cm³/g) and saturation magnetic susceptibility(16.735 emu/g). The quasi-secondary kinetics of RMMBC and the Fre- undlich isothermal model can accurately describe the adsorption process of NOR on RMMBC, indicating that chemisorption may be the main mechanism of NOR adsorption on RMMBC, mainly including IT-IT interaction, surface complexation, hydrophobicity, hydrogen bonding and electrostatic interaction. The use of red mud and waste bacterial residue to prepare magnetic biochar adsorption effect is remarkable, which has the advantage of easy separation from the water body to avoid secondary pollution to the environment, which not only provides new ideas for low-cost treatment of antibiotic wastewater, but also helps to realize the stability, harmlessness and resource utilization of red mud and waste bacterial residue, and achieves the environmental protection goal of "waste treatment". [ABSTRACT FROM AUTHOR]