Influence of biomass feedstocks on magnetic biochar preparation for efficient Pb(II) removal

Jun Dong, Peikun Jiang, Hailong Wang, Ruohui Lu, Yinxiu Liu, Yin Li, Yaping Gan, Nanthi Bolan
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Abstract

Biomass feedstocks have different physicochemical properties owing to their composition, morphology, functional groups, and surface chemistry, leading to considerable differences in the adsorption capacity of their biochars. However, few studies have focused on selecting appropriate biomass feedstocks for the adsorption of Pb(II) and other potentially toxic elements from wastewater. In addition, the effect of magnetic modification on various biomass feedstocks remains unclear. In this study, three types of biomass feedstocks, including fir wood, bamboo wood, and rice straw, were used to prepare biochars (BFW, BBW, and BRS) and magnetic biochars (MagFW, MagBW, and MagRS). Results showed that the Langmuir adsorption capacity of BRS reached 153 mg/g for Pb(II), which was approximately 2.8 and 1.9 times that of BFW and BBW, respectively. The higher Pb(II) adsorption of BRS primarily resulted from its rich mineral content, relatively high pH, and abundant oxygen-containing functional groups, which strengthened the release of alkali/alkaline earth metal cations, precipitation of (hydro)cerussite, ion exchange with H+, and complexation by hydroxyl and carboxyl groups. Magnetic modification changed mainly the surface charge, pH, and surface functional groups of various biochars, thus improving their Pb(II) adsorption capacity through electrostatic attraction, ion exchange, and complexation. Specifically, MagFW (308 mg/g) and MagBW (284 mg/g) demonstrated a more pronounced increase in Pb(II) adsorption capacity than MagRS (297 mg/g), because of the enhanced mineral precipitation and complexation with the FeO band. Results from this study suggest that the application of biochar may be a feasible, effective, and eco-friendly strategy for removing Pb(II) from wastewater.
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生物质原料对制备磁性生物炭高效去除铅(II)的影响
由于生物质原料的组成、形态、官能团和表面化学性质不同,其物理化学性质也不同,导致其生物炭的吸附能力差异较大。然而,很少有研究关注于选择合适的生物质原料来吸附废水中的铅(II)和其他潜在的有毒元素。此外,磁改性对各种生物质原料的影响尚不清楚。本研究以杉木、竹木和稻草为原料,制备生物炭(BFW、BBW和BRS)和磁性生物炭(MagFW、MagBW和MagRS)。结果表明,BRS对Pb(II)的Langmuir吸附量可达153 mg/g,分别约为BFW和BBW的2.8和1.9倍。BRS对Pb(II)的高吸附主要是由于其丰富的矿物含量、较高的pH值和丰富的含氧官能团,这些官能团加强了碱/碱土金属阳离子的释放、(氢化)锡矿的沉淀、与H+的离子交换以及羟基和羧基的络合作用。磁改性主要改变了各种生物炭的表面电荷、pH和表面官能团,从而通过静电吸引、离子交换和络合作用提高了生物炭对Pb(II)的吸附能力。其中,MagFW (308 mg/g)和MagBW (284 mg/g)对Pb(II)的吸附能力比MagRS (297 mg/g)表现出更明显的提高,这是由于矿物沉淀和与FeO波段的络合作用增强。本研究结果表明,生物炭的应用可能是一种可行、有效和环保的去除废水中Pb(II)的策略。
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