# Stable high-pressure phases in the H-S system determined by chemically   reacting hydrogen and sulfur

**Authors:** Alexander F. Goncharov (1,2), Sergey S. Lobanov (2,3), Vitali B., Prakapenka (4), Eran Greenberg (4) ((1) Key Laboratory of Materials Physics,, Institute of Solid State Physics CAS, (2) Geophysical Laboratory, Carnegie, Institution of Washington, Washington, (3) Sobolev Institute of Geology and, Mineralogy, Siberian Branch Russian Academy of Sciences, (4) Center for, Advanced Radiations Sources, University of Chicago)

arXiv: 1702.02522 · 2017-04-19

## TL;DR

This study combines experimental and theoretical methods to identify and characterize stable high-pressure phases of hydrogen sulfide, revealing phase transformations and stability ranges relevant to high-pressure chemistry.

## Contribution

It provides new experimental evidence for high-pressure phases of H3S and their transformations, confirming theoretical predictions and detailing structural changes under pressure.

## Key findings

- H3S phases are stable at high pressures above 140 GPa.
- Transformation from Im-3m to R3m H3S occurs upon pressure release.
- Cccm H3S transforms to a molecular H2S-H2 structure below 40 GPa.

## Abstract

Synchrotron X-ray diffraction and Raman spectroscopy have been used to study chemical reactions of molecular hydrogen (H2) with sulfur (S) at high pressures. We find theoretically predicted Cccm and Im-3m H3S to be the reaction products at 50 and 140 GPa, respectively. Im-3m H3S is a stable crystalline phase above 140 GPa and it transforms to R3m H3S on pressure release below 140 GPa. The latter phase is (meta)stable down to at least 70 GPa where it transforms to Cccm H3S upon annealing (T<1300 K) to overcome the kinetic hindrance. Cccm H3S has an extended structure with symmetric hydrogen bonds at 50 GPa and upon decompression it experiences a transformation to a molecular mixed H2S-H2 structure below 40 GPa without any apparent change in the crystal symmetry.

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Source: https://tomesphere.com/paper/1702.02522