Pressure-induced Transformations of Dense Carbonyl Sulfide to Singly Bonded Amorphous Metallic Solid

The application of internal or external pressure transforms molecular solids into non-molecular extended solids with diverse crystal structures and electronic transport properties. Here, we present pressure-induced phase transitions and associated structural and electric transitions of carbonyl sulfide (OCS) using Raman spectroscopy, X-ray diffraction, resistivity measurement and pair distribution function (PDF) analysis. Linear molcular OCS(R3m, Phase I) transforms to bent OCS (Cm, Phase II) at 9 GPa, an amorphous, one-dimensional (1D) polymer at 20 GPa (Phase III), and an extended 3D network above ~35 GPa (Phase IV) that metallizes at ~105 GPa. Series of phase transformations reveal that long-range dipole interaction plays an important role in the transition regime of dense molecular solid and intermediate nature of OCS between its two isovalent end members of CO$_2$ and CS$_2$ leads to an important chemical concept for the extended molecular alloy.