Recent advances in layered double hydroxide (LDH)-based materials: fabrication, modification strategies, characterization, promising environmental catalytic applications, and prospective aspects

IF 3.2 Q2 CHEMISTRY, PHYSICAL Energy advances Pub Date : 2024-08-05 DOI:10.1039/D4YA00272E
Amal A. Altalhi, Eslam A. Mohamed and Nabel A. Negm
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Abstract

Layered double hydroxides (LDHs) are clay networks with brucite (Mg(OH2)) layers that are coupled with anions between the produced layers. The building structure of LDHs follows the formula [M1−x2+Mx3+(OH)2]x+(An)x/n·yH2O, where M3+ and M2 are trivalent and divalent cations in the structural units (sheets), respectively; x is the M3+ to (M2+ + M3+) cation ratio of the structure; and An is an interlayer anion. LDHs can be created utilizing simple approaches that regulate the layer structure, chemical composition, and shape of the crystals generated by adapting production parameters. The first method of modifying LDH composites is through intercalation, involving the insertion of inorganic or organic precursors into their composition, which can then be employed for a variety of purposes. The next method is a simple physical mixing technique between the created LDHs and advanced materials, such as activated carbon, graphene and its derivatives, and carbon nanotubes, for utilization as base substances in energy storage, supercapacitors, photo- and electrocatalysts, water splitting, and toxic gas removal from the surrounding environment. The final strategy is the synthesis of polymer–LDH composites by inserting effective polymers during the manufacturing process of LDHs to create nano-composites that can be utilized for energy, fire retardant, gas barrier, and wastewater cleaning applications. LDHs are a type of fine chemical that can be designed to have a desired chemical structure and performance for various purposes, such as redox reactions, bromination, ethoxylation, aldol condensation, NOx and SOx elimination, and biofuel production. Because LDH substances are not harmful to the environment, their different applications are unique in terms of green chemistry as they are recyclable and eco-friendly catalysts. The present review investigated the various methods used to create LDHs and the improvement of the produced composites via enhanced temperature calcination; intercalation of their structures by small-, medium-, and high-nuclear anions; and support by carbon compounds. The evaluation methods and the best prospective uses, such as biofuel generation, catalysis, water splitting, charge transfer, and wastewater treatment, are comprehensively reported according to the most current studies, and the future directions of LDHs are highlighted.

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层状双氢氧化物(LDH)基材料的最新进展:制备、改性策略、表征、有前景的环境催化应用及展望
层状双氢氧化物(LDHs)是具有青金石(Mg(OH2))层的粘土网络,在生成的层之间有阴离子耦合。层状双氢氧化物的结构式如下[其中 M3+ 和 M2 是结构单元(薄片)中的三价和二价阳离子,x 是结构中 M3+ 与(M2++M3+)阳离子的比率,An 是层间阴离子。LDH 可以利用简单的方法制造,通过调整生产参数来调节层结构、化学成分和所生成晶体的形状。改变 LDH 复合材料的第一种方法是插层法,即在其成分中插入无机或有机前体,然后将其用于各种用途。第二种方法是在已生成的 LDH 以及活性炭、石墨烯及其衍生物和碳纳米管等先进材料之间采用简单的物理混合技术,将其作为基础物质用于能源储存、超级电容器、光催化剂和电催化剂、水分离以及清除周围环境中的有毒气体。最后一种策略是合成聚合物-LDH 复合材料,在制造 LDH 的过程中加入有效的聚合物,以制造纳米复合材料,用于能源、阻燃、气体阻隔和废水清洁。LDH 是一种精细化学品,可以设计成所需的化学结构和性能,用于氧化还原反应、溴化、乙氧基化、醛醇缩合、消除氮氧化物和硫氧化物以及生物燃料生产等多种用途。由于 LDH 物质对环境无害,使用它们的不同应用在绿色化学方面具有独特性,因为它们是可回收的环保催化剂。本综述研究了用于制备 LDH 的各种方法,以及通过高温煅烧、小核、中核和高核阴离子对其结构的插层和碳化合物的支撑来改进所生产的复合材料。根据目前的最新研究,全面报告了评估方法以及生物燃料生成、催化、水分离、电荷转移和废水处理等最佳前瞻性用途,并强调了 LDHs 的潜在前景。
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Correction: Steady states and kinetic modelling of the acid-catalysed ethanolysis of glucose, cellulose, and corn cob to ethyl levulinate. Back cover Fabrication methods, pseudocapacitance characteristics, and integration of conjugated conducting polymers in electrochemical energy storage devices Inside back cover Back cover
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