![The Synthesis of [Sn<sub></noscript>10</sub>(Si(SiMe<sub>3</sub>)<sub>3</sub>)<sub>4</sub>]<sup>2</sup><sup>-</sup> Using a Metastable Sn(I) Halide Solution Synthesized via a Co-condensation Technique](https://app.jove.com//_next/image?url=https://cloudfront.jove.com/CDNSource/teasers/54498.jpg&w=828&q=75)
Abstract
The simultaneous presence of hydride (H-) and oxide (O2-) anions in an inorganic material is thermodynamically challenging. Oxyhydrides have always been synthesized from an oxide precursor, by using high-temperature solid-state reaction using a mixture of oxide and hydride, topochemical reduction at mild temperatures, or high-pressure synthesis. Here, we introduce a novel and unprecedented synthesis route for transition metal oxyhydrides, where the starting material is not an oxide but an intermetallic compound, LaScSi. The topochemical synthesis of LaScSiOxHy (x ≈ 0.5, y ≈ 1) occurs through water dissociation, highlighting the exceptional catalytic behavior of the electride-type parent material. The topochemical insertion of oxygen and hydrogen transforms LaScSi into a more two-dimensional material and modifies its electronic properties, altering its transport properties, from three-dimensional metallic to semimetallic. This innovative path to oxyhydrides is also of fundamental interest for catalysis: it could open the way for new methods of hydrogen production and storage, especially in water splitting, bypassing traditional processes such as electrolysis or photocatalysis.
