揭示层状氢氧化钇煅烧时结构演变的固态核磁共振和理论建模综合研究

IF 2.624
Yanxin Liu , Xinyue Sheng , Hui Ding, Jun Xu
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引用次数: 0

摘要

层状稀土氢氧化物(LREHs)是离子交换型层状金属氢氧化物的一个新家族,由于层状结构中稀土阳离子的独特性质和阴离子交换能力,它在各个领域都有广泛的应用。将层状金属氢氧化物转化为可通过记忆效应复原的新层状相对于其化学性质和应用至关重要。然而,迄今为止,这些新相的结构细节,如稀土阳离子/反离子的配位环境及其随煅烧温度变化的演变情况仍不清楚。在此,我们采用了一种全面的 89Y/35Cl 固态核磁共振(ssNMR)和理论建模方法来揭示具有代表性的 LREH(即 LYH-Cl)在煅烧过程中的结构演变。我们首先确定了脱水阶段 Y3O(OH)5Cl2 和 Y(OH)3 的部分分解产物,然后揭示了脱羟基阶段氢氧根离子在与氯配位的钇位点上的优先去除,最后确定了脱氯阶段暴露在层表面的氯的优先去除。ssNMR实验显示,煅烧时 Y3+ 和 Cl- 的配位环境发生了显著变化。这些发现帮助我们克服了通过记忆效应合理设计和合成基于 LREH 的功能材料的障碍,凸显了ssNMR 在加深对层状金属氢氧化物及相关材料的理解方面的巨大潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A comprehensive solid-state NMR and theoretical modeling study to reveal the structural evolution of layered yttrium hydroxide upon calcination

A comprehensive solid-state NMR and theoretical modeling study to reveal the structural evolution of layered yttrium hydroxide upon calcination

Layered rare earth hydroxides (LREHs) are a new family of ion-exchangeable layered metal hydroxides, which have extensive applications in various fields due to the unique properties of rare earth cations in the layered structure and the anion exchange capacity. The transformation of layered metal hydroxides to new layered phases that can be restored through the memory effect is critical for their chemistry and applications. However, the structure details of these new phases such as the coordination environments of rare earth cations/counterions and their evolution as a function of calcination temperature remain unclear to date. Herein, a comprehensive 89Y/35Cl solid-state NMR (ssNMR) and theoretical modeling approach was used to reveal the structural evolution of a representative LREH, namely LYH-Cl, upon calcination. We first identified partial decomposition products of Y3O(OH)5Cl2 and Y(OH)3 during the dehydration stage, then uncovered the preferential removal of hydroxide ions on yttrium sites coordinated with chlorine during the dehydroxylation stage, and finally determined the preferential removal of chlorine exposed to the surface of layers during the dechlorination stage. The coordination environments of Y3+ and Cl undergo significant changes upon calcination, revealed by ssNMR experiments. These findings thus help us to overcome the obstacles impeding the rational design and synthesis of LREH-based functional materials via memory effect, underscoring the vast potential of ssNMR in deepening the understanding of layered metal hydroxides and related materials.

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