IMMOBILIZATION EFFECT OF SLUDGE BIOCHAR ON HEAVY METALS IN CONTAMINATED DREDGED SEDIMENT IN RIVER CHANNELS IN MINING REGION
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摘要: 为研究污泥生物炭对矿区河道受污染的疏浚底泥中Cu、Pb和Cd的固化效果,以市政污泥为原料在500℃缺氧条件下制备污泥生物炭,结合扫描电镜、FTIR和XPS等表征手段,分析污泥生物炭投加比对疏浚底泥中3种重金属形态分布和固化效果的影响。结果表明:污泥生物炭的投加可提高疏浚底泥中重金属的稳定化形态,投加比为1.0%时,疏浚底泥中Cu、Pb和Cd稳定态(可氧化态和残渣态)占比分别提高了37.7%、42.9%和42.4%。污泥生物炭主要通过络合反应和沉淀作用固化重金属,经污泥生物碳固化后,底泥中Cu、Pb和Cd的浸出浓度分别由处理前的0.8763,0.0574,0.0185 mg/L降低到0.2527,0.0106,0.0013 mg/L,浸出浓度低于GB 3838—2002《地表水环境质量标准》的Ⅲ类标准限制,处理后的疏浚底泥可进行资源化利用,基本不会产生重金属二次溶出的风险。Abstract: To clarify the immobilization effect of sludge biochar on Cu, Pb, and Cd in dredged sediment contaminated by river channel in a mining region, this study used the municipal sludge as raw material to prepare sludge biochar under anoxic condition at 500 ℃, analyzed the influences of addition ratios of different sludge biochar on the distribution and immobilization effect of three heavy metals in dredged sediment, combining with characterization methods of scanning electron microscopy, FTIR and XPS. The results showed that the addition of sludge biochar could improve the stabilization forms of heavy metals in dredged sediment. When the addition ratio was 1.0%, the proportion of Cu, Pb, and Cd in the stable(oxidizable and residual) in dredged sediment increased by 37.7%, 42.9%, and 42.4%, respectively. Sludge biochar mainly immobilizes heavy metals through complexation reaction and precipitation. The leaching concentration of Cu, Pb, and Cd in the dredged sediment after sludge biochar immobilized decreased from 0.876 mg/L, 0.057 mg/L and 0.018 mg/L to 0.253 mg/L, 0.011 mg/L and 0.001 mg/L, respectively. Meanwhile, the leaching concentration was lower than the limit of the Class Ⅲ standard of Environmental Quality Standard for Surface Water(GB 3838—2002). The immobilized dredged sediment can be reused as resources with no risk of secondary dissolution of heavy metals.
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