Designed functions of oxide/hydroxide nanosheets via elemental replacement/doping

IF 40.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Kanji Saito, Masashi Morita, Tomohiko Okada, Rattanawadee (Ploy) Wijitwongwan and Makoto Ogawa
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引用次数: 0

Abstract

Partial replacement of one structural element in a solid with another of a similar size was conducted to impart functionality to the solids and modify their properties. This phenomenon is found in nature in coloured gemstones and clay minerals and is used in materials chemistry and physics, endowing materials with useful properties that can be controlled by incorporated heteroelements and their amounts. Depending on the area of research (or expected functions), the replacement is referred to as “isomorphous substitution”, “doping”, etc. Herein, elemental replacement in two-dimensional (2D) oxides and hydroxides (nanosheets or layered materials) is summarised with emphasis on the uniqueness of their preparation, characterisation and application compared with those of the corresponding bulk materials. Among the 2D materials (graphene, metallenes, transition metal chalcogenides, metal phosphate/phosphonates, MXenes, etc.), 2D oxides and hydroxides are characterised by their presence in nature, facile synthesis and storage under ambient conditions, and possible structural variation from atomic-level nanosheets to thicker nanosheets composed of multilayered structures. The heteroelements to be doped were selected depending on the target application objectively; however, there are structural and synthetic limitations in the doping of heteroelements. In the case of layered double hydroxides (single layer) and layered alkali silicates (from single layer to multiple layers), including layered clay minerals (2 : 1 layer), the replacement (commonly called isomorphous substitution) is discussed to understand/design characteristics such as catalytic, adsorptive (including ion exchange), and swelling properties. Due to the variation in their main components, the design of layered transition metal oxide/hydroxide materials via isomorphous substitution is more versatile; in this case, tuning their band structure, doping both holes and electrons, and creating impurity levels are examined by the elemental replacement of the main components. As typical examples, material design for the photocatalytic function of an ion-exchangeable layered titanate (lepidocrocite-type titanate) and a perovskite niobate (KCa2Nb3O10) is discussed, where elemental replacement is effective in designing their multiple functions.

Abstract Image

Abstract Image

通过元素置换/掺杂设计氧化物/氢氧化物纳米片的功能。
将固体中的一种结构元素与另一种类似大小的结构元素进行部分置换,可赋予固体功能并改变其特性。这种现象存在于自然界的彩色宝石和粘土矿物中,并被用于材料化学和物理学中,赋予材料有用的特性,而这些特性可以通过加入的杂元素及其数量来控制。根据研究领域(或预期功能)的不同,这种置换被称为 "同构置换"、"掺杂 "等。本文总结了二维(2D)氧化物和氢氧化物(纳米片或层状材料)中的元素置换,重点是与相应的块状材料相比,它们在制备、表征和应用方面的独特性。在二维材料(石墨烯、金属烯、过渡金属瑀、金属磷酸盐/膦酸盐、MX 烯等)中,二维氧化物和氢氧化物的特点是存在于自然界中,易于合成并可在环境条件下储存,结构变化范围从原子级纳米片到由多层结构组成的较厚纳米片。要掺杂的杂元素是根据目标应用客观地选择的;然而,杂元素的掺杂在结构和合成方面存在限制。对于层状双氢氧化物(单层)和层状碱硅酸盐(从单层到多层),包括层状粘土矿物(2:1 层),讨论了置换(通常称为同构取代),以了解/设计催化、吸附(包括离子交换)和膨胀等特性。由于主要成分的不同,通过同构取代设计层状过渡金属氧化物/氢氧化物材料具有更广泛的用途;在这种情况下,可以通过主要成分的元素取代来研究调整其带状结构、掺杂空穴和电子以及创建杂质级。作为典型例子,我们讨论了离子交换型层状钛酸酯(鳞二茂铁型钛酸酯)和过氧化物铌酸盐(KCa2Nb3O10)的光催化功能材料设计,其中元素置换在设计它们的多种功能方面非常有效。
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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来源期刊
Chemical Society Reviews
Chemical Society Reviews 化学-化学综合
CiteScore
80.80
自引率
1.10%
发文量
345
审稿时长
6.0 months
期刊介绍: Chemical Society Reviews is published by: Royal Society of Chemistry. Focus: Review articles on topics of current interest in chemistry; Predecessors: Quarterly Reviews, Chemical Society (1947–1971); Current title: Since 1971; Impact factor: 60.615 (2021); Themed issues: Occasional themed issues on new and emerging areas of research in the chemical sciences
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