Exploring Mg2+ and Ca2+ Conductors Via Solid-State Metathesis Reactions

Abstract

The scarcity of viable electrode and electrolyte materials vastly hinders the advancement of magnesium and calcium batteries. This study utilises solid-state metathetical reactions involving chalcogen- and pnictogen-based honeycomb layered oxides with alkaline-earth halides/nitrates to synthesise Mg2+- and Ca2+-based materials previously achievable only under high-temperature/high-pressure conditions, as well as new metastable materials with unique crystal versatility. Particularly, we employ metathetical reactions involving Li4MgTeO6, Na2Mg2TeO6, and Na4MgTeO6 with MgCl2/ MgSO4/ Mg(NO3)2. 6H2O or Ca(NO3)2. 4H2O / CaCl2. 2H2O at temperatures not exceeding 500 to produce Mg3TeO6 polymorphs, ilmenite-type CaMg2TeO6/ Mg2CaTeO6, and double perovskite-type Ca2MgTeO6. Thus, we demonstrate that these materials, conventionally requiring gigascale pressures or high temperatures (>1000) for their proper synthesis, are now readily accessible at ambient pressure and considerably lower temperatures. Meanwhile, despite sub-optimal pellet densities, the synthesised ilmenite-type Mg3TeO6 (high-pressure polymorph) and double perovskite-type Ca2M TeO6 (M = Mg, Ca, Zn) materials exhibit remarkable bulk ionic conductivity at room temperature, marking them as promising compositional spaces for exploring novel Mg2+ and Ca2+ conductors. Furthermore, this study extends the applicability of metathetical reactions to attain Mg- or Ca-based antimonates, ruthenates, titanates, phosphates, and silicates, thus opening avenues to novel high-entropy multifunctional nanomaterial platforms with utility in energy storage and beyond.