通过近乎瞬时的阳离子交换实现可蜕变的层状富锂铌和钽氧化物。

IF 3.3 3区 化学 Q2 CHEMISTRY, PHYSICAL
Sarah L Ko, Jordan A Dorrell, Andrew J Morris, Kent J Griffith
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引用次数: 0

摘要

富锂早期过渡金属氧化物是过量可移除锂的来源,可为富锂电池正极提供高能量密度。它们也是全固态电池固态电解质的候选材料。这些高离子化合物在热力学稳定的氧化物相图中并不常见,但软化学路线为探索新的富碱晶体化学提供了另一种选择。在这项研究中,通过离子交换化学发现了一种具有共面[Nb4O16]12-团簇的新型层状多晶体 Li3NbO4。对离子交换反应的更详细研究表明,该反应几乎是瞬间发生的,在几秒钟内晶体体积就改变了 22% 以上。此外,还探讨了 L-Li3NbO4 中共面[Nb4O16]12-转变为稳定立方 c-Li3NbO4 中超四面体[Nb4O16]12- 簇的过程。此外,这一合成途径还扩展到了一种新的层状多晶体 Li3TaO4。利用 6,7Li、23Na 和 93Nb NMR、X 射线衍射、中子衍射和第一原理计算对 A3MO4(A = Li、Na;M = Nb、Ta)进行了核磁共振晶体学研究,以确定局部和长程原子结构,监控异常快速的反应进程,并跟踪从可蜕变层状相到利用高温合成发现的已知化合物的相变过程。研究提出了一种机制,即在短反应时间内保留了一些钠,然后在水洗过程中进行质子交换,形成以氢键桥接共面[Nb4O16]12-团簇的相。这项研究对富锂过渡金属氧化物和相关电池材料以及非框架结构中的离子交换化学具有重要意义。该研究强调了可检测轻元素、局部结构和微妙结构变化的技术在软化学合成中的作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Metastable layered lithium-rich niobium and tantalum oxides via nearly instantaneous cation exchange.

Lithium-rich early transition metal oxides are the source of excess removeable lithium that affords high energy density to lithium-rich battery cathodes. They are also candidates for solid electrolytes in all-solid-state batteries. These highly ionic compounds are sparse on phase diagrams of thermodynamically stable oxides, but soft chemical routes offer an alternative to explore new alkali-rich crystal chemistries. In this work, a new layered polymorph of Li3NbO4 with coplanar [Nb4O16]12- clusters is discovered through ion exchange chemistry. A more detailed study of the ion exchange reaction reveals that it takes place almost instantaneously, changing the crystal volume by more than 22% within seconds. The transformation of coplanar [Nb4O16]12- in L-Li3NbO4 into the supertetrahedral [Nb4O16]12- clusters found in the stable cubic c-Li3NbO4 is also explored. Furthermore, this synthetic pathway is extended to access a new layered polymorph of Li3TaO4. NMR crystallography with 6,7Li, 23Na, and 93Nb NMR, X-ray diffraction, neutron diffraction, and first-principles calculations is applied to A3MO4 (A = Li, Na; M = Nb, Ta) to identify local and long-range atomic structure, to monitor the unusually rapid reaction progression, and to track the phase transitions from the metastable layered phases to the known compounds found using high-temperature synthesis. A mechanism is proposed whereby some sodium is retained at short reaction times, which then undergoes proton exchange during water washing, forming a phase with hydrogen bonds bridging the coplanar [Nb4O16]12- clusters. This study has implications for lithium-rich transition metal oxides and associated battery materials and for ion exchange chemistry in non-framework structures. The role of techniques that can detect light elements, local structure, and subtle structural changes in soft-chemical synthesis is emphasized.

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来源期刊
Faraday Discussions
Faraday Discussions 化学-物理化学
自引率
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259
期刊介绍: Discussion summary and research papers from discussion meetings that focus on rapidly developing areas of physical chemistry and its interfaces
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