Metastable layered lithium-rich niobium and tantalum oxides via nearly instantaneous cation exchange

Abstract

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.

Graphical abstract: Metastable layered lithium-rich niobium and tantalum oxides via nearly instantaneous cation exchange

Supplementary files

Article information

Article type
Paper
Submitted
16 5 2024
Accepted
23 7 2024
First published
20 9 2024

Faraday Discuss., 2024, Advance Article

Metastable layered lithium-rich niobium and tantalum oxides via nearly instantaneous cation exchange

S. L. Ko, J. A. Dorrell, A. J. Morris and K. J. Griffith, Faraday Discuss., 2024, Advance Article , DOI: 10.1039/D4FD00103F

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