Giant pressure-induced volume collapse in the pyrite mineral MnS2

TL;DR

This study reveals an unprecedented 22% volume collapse in the mineral MnS2 under pressure, driven by a novel magnetic mechanism involving dimerisation and metal-metal bonding, with implications for geochemistry and material science.

Contribution

It introduces a new pressure-induced phase transition mechanism in MnS2, distinct from traditional spin-state transitions, involving dimerisation and magnetic quenching.

Findings

22% volume collapse observed in MnS2 under pressure

Formation of a disordered intermediate during compression

Confirmation of a new thermodynamic groundstate with quenched magnetism

Abstract

Dramatic volume collapses under pressure are fundamental to geochemistry and of increasing importance to fields as diverse as hydrogen storage and high-temperature superconductivity. In transition metal materials, collapses are usually driven by so-called spin-state transitions, the interplay between the single-ion crystal field and the size of the magnetic moment. Here we show that the classical S=5/2 mineral Hauerite undergoes an unprecedented 22 % collapse driven by a conceptually different magnetic mechanism. Using synchrotron x-ray diffraction we show that cold compression induces the formation of a disordered intermediate. However, using an evolutionary algorithm we predict a new structure with edge-sharing chains. This is confirmed as the thermodynamic groundstate using in situ laser heating. We show that magnetism is globally absent in the new phase, as low-spin quantum S=1/2 moments are quenched by dimerisation. Our results show how the emergence of metal-metal bonding can stabilise giant spin-lattice coupling in Earth's minerals.