A rutile-based homologous series Na(PtO$_2$)$_{2\it{n}+1}$ discovered by computationally assisted high-pressure synthesis

TL;DR

This paper reports the discovery of a new homologous series of layered platinum oxides, Na(PtO$_2$)$_{2n+1}$, synthesized under high pressure and characterized by unique structural motifs, expanding the landscape of metastable transition metal oxides.

Contribution

The study introduces a novel homologous series of layered platinum oxides with unique structures, identified through a combination of high-pressure synthesis and computational methods.

Findings

Discovery of a new homologous series Na(PtO$_2$)$_{2n+1}$

Identification of unprecedented layered structural motifs

Successful synthesis and structural confirmation through diffuse scattering analysis

Abstract

Layered transition metal oxides typified by the Ruddlesden-Popper phase have been extensively studied for its applications in high-temperature superconductivity, catalysis, and battery technologies. Despite the remarkable structural diversity and catalytic functionality of platinum oxides, the exploration of layered polymorphs has remained significantly constrained mainly due to the high inertness of platinum. Here, we discover a new homologous series of layered ternary oxides, Na(PtO$_2$)$_{2\it{n}+1}$, by a combination of highly oxidizing high-pressure methods and density functional theory (DFT) calculations. This series features unprecedented layered structural motifs, rutile-based PtO$_6$ octahedra and one-dimensional PtO$_4$ square-planar columns, which enables systematic control of dimensionality. Furthermore, we demonstrate a computationally-assisted identification of isomeric and putative members of this homologous series as confirmed by controlled synthesis and quantitative analysis of diffuse scattering data. This approach provides an effective platform for the exhaustive exploration of metastable transition metal oxides with rich structural variations.