利用死细菌生物量和石墨化氮化碳纳米材料对土壤中铅、镉和铜的比较固定化

IF 5.5 Q1 ENGINEERING, CHEMICAL

Chemical Engineering Journal Advances Pub Date : 2025-02-06 DOI:10.1016/j.ceja.2025.100714

Asifa Farooqi , Ejaz ul Haq , Hooria Ikram Raja , Hafiz Abdul Malik , Yousaf Shad Muhammad , Syed Hamza Safeer , Sohail Yousaf , Maximilian Lackner

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引用次数: 0

摘要

众所周知，重金属（HM）对土壤、作物和人类造成严重危害。研究了不同剂量的死菌生物量（BM）和石墨氮化碳（g-C3N4）对尖刺土壤中Pb、Cd和Cu离子的金属固定化效果。BM和g-C3N4对土壤中金属的固定化效果取决于金属特性、吸附剂剂量和接触时间。土壤中加入了两种不同浓度的金属。当比较两种吸附剂时，在金属的固定化方面没有观察到显着差异。结果表明，BM、g-C3N4和金属组分之间存在显著相关性。在200 mg kg-1 BM时，Pb、Cd和Cu的RS分数（残余分数）分别增加了42%、44%和68%。在200 mg kg-1 g-C3N4时，Pb、Cd和Cu的RS分数分别为48%、43%和83%。在孵育的前3天观察到可交换金属分数的最大减少。对金属的吸附随时间的延长而增加。铜的吸附率最高（57%），其次是Cd和Pb。Cd吸附从Cd_125的35%增加到Cd_275的55%。对Cu的吸附没有明显的变化，在Pb_160时，Cu的吸附性较高（35%），在Pb_330时下降到30%。本研究建议使用死细菌生物量作为一种经济、环保的吸附剂来代替化学合成的纳米材料来修复hm污染的土壤。

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Comparative immobilization of lead, cadmium, and copper in soil using dead bacterial biomass and graphitic carbon nitride nanomaterials

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Comparative immobilization of lead, cadmium, and copper in soil using dead bacterial biomass and graphitic carbon nitride nanomaterials

Heavy metals (HM) are known to pose severe harm to the soil, crops, and human beings. The usefulness and efficiency of metal immobilization of Pb, Cd, and Cu ions using different doses of dead bacterial biomass (BM) and graphitic carbon nitride (g-C₃N₄) was evaluated and compared in spiked soil. The effectiveness of BM and g-C₃N₄ to immobilize metals in soil depends on the metal characteristics, dose of adsorbent, and contact time. The soil was spiked with two different metal concentrations. When comparing the two adsorbents, there was no significant difference observed in the immobilization of metals. Results showed a significant relationship between BM, g-C₃N_4, and metal fractions. At 200 mg kg^-1 BM, the increase in the RS fraction (residual fraction) of Pb, Cd, and Cu was 42, 44, and 68 %, respectively. At 200 mg kg^-1 g-C₃N_4, the RS fraction of Pb, Cd, and Cu was 48, 43, and 83 %, respectively. The maximum reduction in the exchangeable metal fraction was observed during the first 3 days of incubation. The adsorption of metals increased with time. Cu showed the highest adsorption (57 %) followed by Cd and Pb. The Cd adsorption increased from 35 % at Cd_125 to ∼55 % at Cd_275. There was no noticeable variation in the adsorption of Cu and relatively higher adsorption (35 %) was observed at Pb_160 and dropped to 30 % at Pb_330. The present study suggests using dead bacterial biomass as a cost-effective and environmentally benign adsorbent for the remediation of HM-contaminated soils instead of chemically synthesized nanomaterials.

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