Facile and environmentally sustainable synthesis of bone waste derived biochar-based bimetallic-LDH nanocomposite for selected dyes removal from aqueous medium

Shanthi Prabha Viswanathan, Giya Merline Kuriakose, Gopika Vijayakumar Njazhakunnathu, Sreekanth Prakasan Neelamury, Thomas Paili Ambatt
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Abstract

The disposal of bone waste can be effectively addressed utilizing a novel approach involving the synthesis of a bovine bone-derived biochar-based Mg/Al-layered double hydroxide (LDH) nanocomposite (B-Mg/Al-NC). This nanocomposite exhibits exceptional capabilities for removing specific dyes, such as Methylene Blue (MB) and Congo Red (CR), from aqueous media. Extensive characterization using techniques confirmed the successful formation of the B-Mg/Al-NC, which possesses a high surface area, high porosity, and abundant functional groups. The Langmuir monolayer biosorption capacity was 395.56 mg g−1 and 328.25 mg g−1 at 50 °C for MB and CR, respectively, with rapid dye removal achieved within 25 min under alkaline pH conditions. The experimental data fit well with the pseudo-second-order kinetics model for both dyes. The remarkable dye adsorption capacity of the B-Mg/Al-NC can be attributed to the combined basic properties of the bone biochar and Mg/Al-LDH. Proposed mechanisms for enhanced dye removal include hydrogen bonding interactions, anion exchange, surface complexation, electrostatic interactions, and pore filling. Furthermore, the nanocomposite exhibited excellent reusability. In addition to its dye removal capabilities, the B-Mg/Al-NC was found to have a positive effect on seed germination and growth and salient soil health parameters, as demonstrated by a rapid seed germination test using the spent composite. Overall, the facile synthesis of the B-Mg/Al-NC via co-precipitation and ultrasonication is a highly recommended and sustainable approach for producing an eco-friendly bio-sorbent with exceptional dye removal efficiency from wastewater while also addressing the issue of bone waste disposal.

Graphical abstract

Abstract Image

Abstract Image

基于骨废物衍生生物炭的双金属-LDH 纳米复合材料的简便和环境可持续合成,用于去除水介质中的特定染料
利用一种新方法,即合成一种基于牛骨生物炭的镁/铝层双氢氧化物(LDH)纳米复合材料(B-Mg/Al-NC),可以有效处理骨废物。这种纳米复合材料在去除水介质中的特定染料(如亚甲基蓝(MB)和刚果红(CR))方面表现出卓越的能力。广泛的表征技术证实了 B-Mg/Al-NC 的成功形成,它具有高比表面积、高孔隙率和丰富的官能团。在碱性 pH 条件下,甲基溴和铬的朗缪尔单层生物吸附容量分别为 395.56 mg g-1 和 328.25 mg g-1,并能在 25 分钟内快速去除染料。实验数据与这两种染料的假二阶动力学模型十分吻合。B-Mg/Al-NC 显著的染料吸附能力可归因于骨生物炭和 Mg/Al-LDH 的综合基本特性。拟议的染料去除增强机制包括氢键相互作用、阴离子交换、表面络合、静电相互作用和孔隙填充。此外,这种纳米复合材料还具有出色的可重复使用性。除染料去除能力外,B-Mg/Al-NC 还对种子发芽和生长以及显著的土壤健康参数有积极影响,使用废复合材料进行的种子快速发芽试验证明了这一点。总之,通过共沉淀和超声波法轻松合成 B-Mg/Al-NC 是一种非常值得推荐的可持续方法,可用于生产一种环保型生物吸附剂,对废水中的染料具有卓越的去除效率,同时还能解决骨废物处理问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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