Abstract
Efficient elimination and retrieval of phosphorus from water bodies are crucial for effective eutrophication management and phosphorus reuse. A novel Fe/Ca oxide co-coated modified biochar (FCBC) was synthesized for phosphate recovery using coconut shell biochar as the raw material with ferrous chloride (FeCl2) and calcium peroxide (CaO2) as precursors. FCBC possesses a highly intricate pore structure and an abundance of surface-active groups. Fe/Ca oxides are loaded onto the biochar in the form of Ca2Fe2O5, Fe2O3, and CaCO3. FCBC demonstrates a broad pH tolerance range (pH = 6 – 12) in the aquatic environment. Phosphorus absorption by FCBC was simulated using the proposed pseudo-second-order kinetic and Langmuir model. The maximal saturation adsorption capacity was found to be 53.31 mg P/g. Phosphorus elimination is influenced by the generation of Ca3(PO4)2, intraparticle diffusion, and electrostatic attraction. FCBC produced demonstrated exceptional phosphorus removal effectiveness in the presence of multiple anions, except for wastewater with high concentrations of SO42-, CO32-, HCO3-, and F- (>500 mg/L). The phosphorus removal effectiveness of FCBC in natural water samples collected from ponds, farmlands, and ditches exceeded 94%. This paper presents a novel technique for creating iron-calcium composite-modified biochar, which offers a valuable method for efficiently recovering phosphorus from agricultural surface waters.