二维纳米通道和巨大的比表面积为水的修复和吸附提供了独特的途径:评估六方氮化硼在分离技术中的优势

Sankeerthana Avasarala, Suryasarathi Bose
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引用次数: 1

摘要

这篇综述强调了将六方氮化硼(BN)结合到目前的膜基结构中用于水修复的优势,而不是其他已经开发好的二维纳米材料,如石墨烯、氧化石墨烯、硫化钼、MXenes。BN的层间距为3.3A0,与石墨烯相似,但比其他二维纳米材料的层间距小。BN是生物惰性的,在恶劣的化学和热条件下是稳定的。当与薄膜复合材料和混合基质膜结构相结合时,氮化硼可以帮助实现高渗透,脱染和脱盐。与氧化石墨烯不同,由BN纳米片组装的层流膜不会在水环境中不受控制地膨胀。BN纳米材料具有较大的比表面积,这意味着更多的吸附位点,并且本质上是疏水性的,这意味着其粉末形式的吸附剂可以很容易地从污染的水中分离出来。氮化硼吸附剂由于其热惰性和化学惰性,可以通过化学药剂处理或加热到高温去除吸附物来再生,而不会损坏氮化硼。氮化硼纳米材料有可能克服目前膜和吸附剂的缺点,同时大大提高膜和吸附剂在水修复中的性能。图形抽象
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2D nanochannels and huge specific surface area offer unique ways for water remediation and adsorption: assessing the strengths of hexagonal boron nitride in separation technology

This review highlights the advantages of incorporating hexagonal Boron Nitride (BN) into the current membrane-based architectures for water remediation over other well-explored 2D nanomaterials such as graphene, graphene oxide, molybdenum sulphide, MXenes. BN has an interlayer spacing of 3.3A0 which is similar to that of graphene, but smaller than that of the other 2D nanomaterials. BN is bioinert, and stable under harsh chemical and thermal conditions. When combined with thin film composite and mixed matrix membrane architectures, BN can help achieve high permeance, dye rejection, and desalination. Laminar membranes assembled by BN nanosheets do not swell uncontrollably in aqueous environments unlike graphene oxide. BN nanomaterials have a large specific surface area which implies more adsorption sites, and are inherently hydrophobic in nature, which means the adsorbent in its powder form can be easily separated from contaminated water. BN adsorbents can be regenerated by treating with chemicals or heating to high temperatures to remove the adsorbate, without damaging the BN, due to its thermal and chemical inertness. BN nanomaterials have the potential to circumvent the current shortcomings of membranes and adsorbents, while greatly enhancing the performance of membranes and adsorbents for water remediation.

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