Synergistic effect of magnetic magnetite and greigite nanoparticles dispersed pinewood biochar for aqueous lead(II) and cadmium(II) adsorption

Cleaner Water Pub Date : 2025-02-03 DOI:10.1016/j.clwat.2025.100068

Prashan M. Rodrigo , Raghava R. Kommalapati

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Abstract

Heavy metals such as lead and cadmium cause adverse effects on all living organisms. Their remediation is complex in the aqueous phase. Biochar is a low-cost, environmentally friendly adsorbent material that exhibited a limited ability to adsorb Pb²⁺ and Cd²⁺. Iron-based magnetite and greigite nanoparticles have proven high adsorption capacity due to high amounts of oxygen and sulfur-contained functional groups per unit volume. In this study, a mixture of greigite and magnetite nanoparticles was simultaneously synthesized on pinewood biochar (BC), aiding co-precipitation from a Fe²⁺/Fe³⁺ and S^2- salts mixture (Fe₃O₄-Fe₃S₄/BC), that offers a cost-effective, sustainable, and efficient material for Pb²⁺ and Cd²⁺ removal. BC, Fe₃O₄-Fe₃S₄/BC, and Pb²⁺ and Cd²⁺ adsorbed Fe₃O₄-Fe₃S₄/BC materials were characterized to differentiate surface morphologies, elemental compositions, and surface chemical states. The Fe₃O₄-Fe₃S₄/BC composite exhibited an average nanoparticle diameter of ∼20 nm. Fe₃O₄-Fe₃S₄/BC showed Langmuir adsorption capacities of 138.9 and 49.5 mg g^-1 for Pb²⁺ and Cd²⁺ at pH 5 (25 °C). Pb²⁺ and Cd²⁺ followed pseudo-second-order kinetics, and the equilibriums were achieved after ∼2 h and ∼30 min, respectively, for 125 and 1250 μmol L^-1 concentrations, respectively, where the fast adsorption rates make Fe₃O₄-Fe₃S₄/BC hybrid system a practical option for real-time treatment. Further, adsorption performances were influenced by ionic strength, dose optimization, and the presence of competing ions, suggesting the potential for fine-tuning adsorbent conditions in practical applications. This study enhanced the understanding of adsorption characteristics for a treatment facility that can effectively remediate lead and cadmium-contaminated wastewater. While there have been studies on using biochar and nanoparticles separately for Pb²⁺ and Cd²⁺ adsorption, this research bridges the gap by demonstrating the synergistic effect for Pb²⁺ and Cd²⁺ adsorption from hybrid magnetite-greigite nanoparticles.

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磁性磁铁矿和灰长铁矿纳米颗粒分散松木生物炭对水中铅（II）和镉（II）吸附的协同效应

铅和镉等重金属对所有生物都有不利影响。它们在水相中的修复是复杂的。生物炭是一种低成本、环保的吸附剂材料，但对Pb2+和Cd2+的吸附能力有限。铁基磁铁矿和灰长铁矿纳米颗粒具有较高的吸附能力，因为它们每单位体积含有大量的含氧和含硫官能团。在本研究中，我们在松木生物炭（BC）上同时合成了一种灰长铁矿和磁铁矿的纳米颗粒混合物，帮助从Fe2+/Fe3+和S2-盐混合物（Fe3O4-Fe3S4/BC）中共沉淀，为去除Pb2+和Cd2+提供了一种经济、可持续和高效的材料。对BC、Fe3O4-Fe3S4/BC、Pb2+和Cd2+吸附Fe3O4-Fe3S4/BC材料的表面形貌、元素组成和表面化学状态进行了表征。Fe3O4-Fe3S4/BC复合材料的平均纳米颗粒直径为~ 20 nm。Fe3O4-Fe3S4/BC对Pb2+和Cd2+的Langmuir吸附量分别为138.9和49.5 mg g-1。Pb2+和Cd2+遵循准二级动力学，分别在125和1250 μmol L-1浓度下，分别在~ 2 h和~ 30 min后达到平衡，其中快速的吸附速率使Fe3O4-Fe3S4/BC混合体系成为实时处理的实用选择。此外，吸附性能受离子强度、剂量优化和竞争离子存在的影响，表明在实际应用中微调吸附剂条件的潜力。本研究增加了对吸附特性的认识，为有效修复铅镉污染废水的处理设施提供了基础。虽然已有研究分别使用生物炭和纳米颗粒吸附Pb2+和Cd2+，但本研究通过展示磁铁矿-灰长铁矿混合纳米颗粒吸附Pb2+和Cd2+的协同效应，弥补了这一空白。

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Cleaner Water

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