Isaac K. Tetteh , Ibrahim Issahaku , Antonia Y. Tetteh
{"title":"活性碳及其他碳衍生物的合成、表征和环境应用方面的最新进展","authors":"Isaac K. Tetteh , Ibrahim Issahaku , Antonia Y. Tetteh","doi":"10.1016/j.cartre.2024.100328","DOIUrl":null,"url":null,"abstract":"<div><p>The historicity and versatility of activated carbons (ACs) and other carbon derivatives (OCDs) date back to antiquity. This article reviews the recent advances in synthesis, characterization, and environmental applications of these demand-driven adsorbents from biomass and non-biomass sources. It first identifies relevant literature sources and knowledge gaps and then segmentalizes and scrutinizes the theme to elucidate contemporary carbon-based adsorbents. Conventional and advanced syntheses are highlighted. Current trends in adsorbents' characterization and remediation are also presented. The conventional AC synthesis includes one-step or two-step chemical or physical activation or a combinatorial synthesis of the two. Issues in the combinatorics are examined. Advanced techniques such as hydrothermal carbonization/activation and microwave-assisted irradiation are described, which may also involve one-step or two-step procedures. OCDs, including carbon nanotubes, carbon nanofibers, and carbon dots, mainly employ advanced syntheses, for example, nanotechnology. Currently, ACs and OCDs are mainly characterized using advanced techniques like scanning electron microscopy (SEM), Fourier transform infrared (FTIR) spectroscopy, thermogravimetric analysis (TGA), nitrogen (N<sub>2</sub>) adsorption, and X-ray diffraction (XRD), which elucidate their structures, properties, and potential efficacies. Their applications for removing water, soil, and air pollutants are evaluated. The highest percent removal efficiency was activation type-specific, reflecting the precursor's nature, synthesis method, product properties, and quality. For instance, the chemical activation of neem leaves by H<sub>3</sub>PO<sub>4</sub> activation and Fe nanoparticles from tea extracts were 100% successful for Pb<sup>2+</sup>and Cr<sup>6+</sup>, respectively, whereas physical activation of rice husk produced 91.8% success for Cr<sup>3+</sup>. However, their differential adsorptivities for other metals were moderate, with H<sub>3</sub>PO<sub>4</sub> activation the lowest. Due to the high cost, tedious processes in producing and restoring ACs, and their non-selectiveness, researchers continually search for suitable alternatives, which this review considers. Also, applying artificial intelligence (AI) techniques in advancing novel ACs and OCDs for environmental remediation is discussed. 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This article reviews the recent advances in synthesis, characterization, and environmental applications of these demand-driven adsorbents from biomass and non-biomass sources. It first identifies relevant literature sources and knowledge gaps and then segmentalizes and scrutinizes the theme to elucidate contemporary carbon-based adsorbents. Conventional and advanced syntheses are highlighted. Current trends in adsorbents' characterization and remediation are also presented. The conventional AC synthesis includes one-step or two-step chemical or physical activation or a combinatorial synthesis of the two. Issues in the combinatorics are examined. Advanced techniques such as hydrothermal carbonization/activation and microwave-assisted irradiation are described, which may also involve one-step or two-step procedures. OCDs, including carbon nanotubes, carbon nanofibers, and carbon dots, mainly employ advanced syntheses, for example, nanotechnology. Currently, ACs and OCDs are mainly characterized using advanced techniques like scanning electron microscopy (SEM), Fourier transform infrared (FTIR) spectroscopy, thermogravimetric analysis (TGA), nitrogen (N<sub>2</sub>) adsorption, and X-ray diffraction (XRD), which elucidate their structures, properties, and potential efficacies. Their applications for removing water, soil, and air pollutants are evaluated. The highest percent removal efficiency was activation type-specific, reflecting the precursor's nature, synthesis method, product properties, and quality. For instance, the chemical activation of neem leaves by H<sub>3</sub>PO<sub>4</sub> activation and Fe nanoparticles from tea extracts were 100% successful for Pb<sup>2+</sup>and Cr<sup>6+</sup>, respectively, whereas physical activation of rice husk produced 91.8% success for Cr<sup>3+</sup>. However, their differential adsorptivities for other metals were moderate, with H<sub>3</sub>PO<sub>4</sub> activation the lowest. 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引用次数: 0
摘要
活性碳(AC)和其他碳衍生物(OCD)的历史性和多功能性可以追溯到古代。本文回顾了这些以需求为导向的生物质和非生物质吸附剂在合成、表征和环境应用方面的最新进展。文章首先确定了相关的文献来源和知识空白,然后对主题进行了细分和审查,以阐明当代的碳基吸附剂。重点介绍了传统和先进的合成方法。此外,还介绍了吸附剂表征和修复方面的当前趋势。传统的 AC 合成包括一步或两步化学或物理活化,或两者的组合合成。对组合合成中的问题进行了研究。介绍了水热碳化/活化和微波辅助辐照等先进技术,这些技术也可能涉及一步或两步程序。包括碳纳米管、碳纳米纤维和碳点在内的 OCD 主要采用先进的合成方法,例如纳米技术。目前,AC 和 OCD 主要采用扫描电子显微镜(SEM)、傅立叶变换红外光谱(FTIR)、热重分析(TGA)、氮(N2)吸附和 X 射线衍射(XRD)等先进技术进行表征,从而阐明其结构、性质和潜在功效。评估了它们在去除水、土壤和空气污染物方面的应用。最高的去除率与活化类型有关,反映了前驱体的性质、合成方法、产品特性和质量。例如,通过 H3PO4 活化楝树叶和从茶叶提取物中提取铁纳米粒子的化学活化法对 Pb2+ 和 Cr6+ 的去除率分别为 100%,而稻壳的物理活化法对 Cr3+ 的去除率为 91.8%。不过,它们对其他金属的吸附性差异不大,其中 H3PO4 活化的吸附性最低。由于 AC 的成本高、生产和还原过程繁琐以及其非选择性,研究人员一直在寻找合适的替代品,本综述对此进行了探讨。此外,还讨论了如何应用人工智能(AI)技术推进新型 AC 和 OCD 的环境修复。最后,提出了未来的研究方向。
Recent advances in synthesis, characterization, and environmental applications of activated carbons and other carbon derivatives
The historicity and versatility of activated carbons (ACs) and other carbon derivatives (OCDs) date back to antiquity. This article reviews the recent advances in synthesis, characterization, and environmental applications of these demand-driven adsorbents from biomass and non-biomass sources. It first identifies relevant literature sources and knowledge gaps and then segmentalizes and scrutinizes the theme to elucidate contemporary carbon-based adsorbents. Conventional and advanced syntheses are highlighted. Current trends in adsorbents' characterization and remediation are also presented. The conventional AC synthesis includes one-step or two-step chemical or physical activation or a combinatorial synthesis of the two. Issues in the combinatorics are examined. Advanced techniques such as hydrothermal carbonization/activation and microwave-assisted irradiation are described, which may also involve one-step or two-step procedures. OCDs, including carbon nanotubes, carbon nanofibers, and carbon dots, mainly employ advanced syntheses, for example, nanotechnology. Currently, ACs and OCDs are mainly characterized using advanced techniques like scanning electron microscopy (SEM), Fourier transform infrared (FTIR) spectroscopy, thermogravimetric analysis (TGA), nitrogen (N2) adsorption, and X-ray diffraction (XRD), which elucidate their structures, properties, and potential efficacies. Their applications for removing water, soil, and air pollutants are evaluated. The highest percent removal efficiency was activation type-specific, reflecting the precursor's nature, synthesis method, product properties, and quality. For instance, the chemical activation of neem leaves by H3PO4 activation and Fe nanoparticles from tea extracts were 100% successful for Pb2+and Cr6+, respectively, whereas physical activation of rice husk produced 91.8% success for Cr3+. However, their differential adsorptivities for other metals were moderate, with H3PO4 activation the lowest. Due to the high cost, tedious processes in producing and restoring ACs, and their non-selectiveness, researchers continually search for suitable alternatives, which this review considers. Also, applying artificial intelligence (AI) techniques in advancing novel ACs and OCDs for environmental remediation is discussed. Finally, future research dimensions are proposed.