# High-pressure synthesis of ultraincompressible hard rhenium nitride   pernitride Re$_{2}$(N$_{2}$)N$_{2}$ stable at ambient conditions

**Authors:** Maxim Bykov, Stella Chariton, Hongzhan Fei, Timofey Fedotenko,, Georgios Aprilis, Alena V. Ponomareva, Ferenc Tasn\'adi, Igor A. Abrikosov,, Benoit Merle, Patrick Feldner, Sebastian Vogel, Wolfgang Schnick, Vitali B., Prakapenka, Eran Greenberg, Michael Hanfland, Anna Pakhomova, Hanns-Peter, Liermann, Tomoo Katsura, Natalia Dubrovinskaia, Leonid Dubrovinsky

arXiv: 1902.09249 · 2020-01-06

## TL;DR

This paper reports the synthesis and characterization of a novel, ultrahard, and ultraincompressible rhenium nitride pernitride Re₂(N₂)N₂, which is stable at ambient conditions and exhibits unique crystal chemistry and exceptional properties.

## Contribution

It introduces a new rhenium nitride pernitride with unique crystal chemistry and demonstrates a scalable synthesis method from high-pressure to ambient conditions.

## Key findings

- Re₂(N₂)N₂ has a bulk modulus of 428 GPa.
- It exhibits a nanoindentation hardness of 36.7 GPa.
- The material is recoverable at ambient conditions.

## Abstract

Here we report the synthesis of metallic, ultraincompressible (bulk modulus $K_{0}$ = 428(10) GPa) and very hard (nanoindentation hardness 36.7(8) GPa) rhenium (V) nitride pernitride Re$_{2}$(N$_{2}$)N$_{2}$. While the empirical chemical formula of the compound, ReN$_{2}$, is the same as for other known transition metals pernitrides, e.g. IrN$_{2}$, PtN$_{2}$, PdN$_{2}$ and OsN$_{2}$, its crystal chemistry is unique. The known pernitrides of transition metals consist of a metal in the oxidation state +IV and pernitride anions N$_{2}^{4-}$. ReN$_{2}$ contains both pernitride N$_{2}^{4-}$ and discrete N$^{3-}$ anions, which explains its exceptional properties. Moreover, in the original experimental synthesis of Re$_{2}$(N$_{2}$)N$_{2}$ performed in a laser-heated diamond anvil cell via a direct reaction between rhenium and nitrogen at pressures from 40 to 90 GPa we observed that the material was recoverable at ambient conditions. Consequently, we developed a route to scale up its synthesis through a reaction between rhenium and ammonium azide, NH$_{4}$N$_{3}$, in a large-volume press at 33 GPa. Our work resulted not only in a discovery of a novel material with unusual crystal chemistry and a set of properties attractive for potential applications, but also demonstrated a feasibility of surmounting conceptions common in material sciences.

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Source: https://tomesphere.com/paper/1902.09249