Archive/Waste Control by Waste: Red Mud-Based Porous Carbothermal Composite for Efficient Remediation of Manganese and Ammonia Nitrogen in Contaminated Soil
Waste Control by Waste: Red Mud-Based Porous Carbothermal Composite for Efficient Remediation of Manganese and Ammonia Nitrogen in Contaminated Soil
Xinyue Shi, He Shang, Lei Wang et al.
17 de julho de 2026
en

Abstract

The co-contamination of manganese ions (Mn2+) and ammonia nitrogen (NH4+) caused by the stockpiling of manganese residue poses a serious threat to the ecological environment. In this study, a series of the composite was prepared from red mud, bentonite, and corn straw via oxygen-limited pyrolysis. The effects of pyrolysis temperature and raw material ratio on the material properties were investigated, and the synergistic remediation performance of the composites for Mn2+ and NH4+ in manganese residue-contaminated soil was evaluated through a 180-day soil column experiment. The results showed that the composite prepared with a raw material ratio of 1:1:1 at a pyrolysis temperature of 700 °C exhibited the largest specific surface area and the most developed pore structure, achieving a Mn2+ removal rate of 92.72% ± 0.85% in aqueous solution. In the soil column experiment, the material prepared at 700 °C gave the highest immobilization rate for soil Mn2+ (96.22% ± 0.5%), whereas the combined addition of materials prepared at 700 °C and 500 °C achieved the best removal efficiency for NH4+ (99.33% ± 0.23%). Mechanistic studies revealed that the stabilization of Mn2+ is primarily attributable to alkaline precipitation and mineral lattice solid solution induced by the composite, leading to the formation of stable spinel phases (e.g., (Fe,Mn)3O4) and insoluble manganese phosphate-carbonate salts. The removal of NH4+ is proposed to proceed via adsorptive enrichment by the porous structure and Fe0-mediated Fenton-like catalytic oxidation, ultimately converting NH4+ to N2 gas. The 180-day monitoring results demonstrated that the remediation effect continuously increased over time, indicating good long-term stability of the composite. This study provides an efficient, low-cost functional material derived from solid waste for the remediation of manganese residue-contaminated soil and offers a theoretical basis for the synergistic resource utilization of multiple solid wastes.

IPC Classification

C07A01

Keywords

wastecontrolmud-basedporouscarbothermalcompositeefficientremediationmanganeseammonianitrogencontaminatedsoilmaterialsco-contaminationionscausedstockpilingresidueposesseriousthreatecologicalenvironment
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