将椰枣穗状花序增值为活性炭衍生复合材料用于甲基橙吸附：推进废水处理中的循环生物经济——对其平衡、动力学、热力学和机制的综合研究。

Valorizing date palm spikelets into activated carbon-derived composite for methyl orange adsorption: advancing circular bioeconomy in wastewater treatment-a comprehensive study on its equilibrium, kinetics, thermodynamics, and mechanisms.

机构信息

Laboratory of LARGHYDE, University of Biskra, P.O. Box 145, 07000, Biskra, Algeria.

Department of Industrial Chemistry, University of Biskra, P.O. Box 145, 07000, Biskra, Algeria.

出版信息

Environ Sci Pollut Res Int. 2024 Aug;31(38):50493-50512. doi: 10.1007/s11356-024-34581-3. Epub 2024 Aug 3.

DOI:10.1007/s11356-024-34581-3

PMID:39096460

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11364697/

Abstract

Leveraging date palm spikelets (DPS) as a precursor, this study developed a DPS-derived composite (ZnO@DPS-AC) for water treatment, focusing on methyl orange (MO) removal. The composite was synthesized through ZnCl2 activation and pyrolysis at 600 °C. Comprehensive characterization was conducted using TGA, FTIR, XRD, SEM/EDS, and pH. Characterization revealed a highly carbonaceous material (> 74% carbon) with significant porosity and surface functional groups. ZnO@DPS-AC demonstrated rapid MO removal, achieving over 45% reduction within 10 min and up to 99% efficiency under optimized conditions. The Langmuir model-calculated maximum adsorption capacity reached 226.81 mg/g at 20 °C. Adsorption mechanisms involved hydrogen bonding, π-π interactions, and pore filling. The composite showed effectiveness in treating real wastewater and removing other pollutants. This study highlights the potential of agricultural waste valorization in developing efficient, sustainable adsorbents for water remediation, contributing to circular bioeconomy principles.

摘要

利用海枣小穗（DPS）作为前体，本研究开发了一种 DPS 衍生的复合材料（ZnO@DPS-AC）用于水处理，重点去除甲基橙（MO）。该复合材料通过 ZnCl2 活化和 600°C 热解合成。采用 TGA、FTIR、XRD、SEM/EDS 和 pH 值进行综合表征。表征结果表明，该复合材料具有高度碳化的材料（>74%的碳），具有显著的孔隙率和表面官能团。ZnO@DPS-AC 对 MO 的去除具有快速的特点，在 10 分钟内实现超过 45%的去除率，在优化条件下可达到 99%的去除效率。在 20°C 下，Langmuir 模型计算的最大吸附容量达到 226.81mg/g。吸附机制涉及氢键、π-π 相互作用和孔填充。该复合材料在处理实际废水和去除其他污染物方面表现出有效性。本研究强调了农业废物增值利用在开发高效、可持续的水修复吸附剂方面的潜力，符合循环生物经济原则。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f3ca/11364697/71c2b2ddcf95/11356_2024_34581_Fig1_HTML.jpg

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将椰枣穗状花序增值为活性炭衍生复合材料用于甲基橙吸附：推进废水处理中的循环生物经济——对其平衡、动力学、热力学和机制的综合研究。

Valorizing date palm spikelets into activated carbon-derived composite for methyl orange adsorption: advancing circular bioeconomy in wastewater treatment-a comprehensive study on its equilibrium, kinetics, thermodynamics, and mechanisms.

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