Three binary fcc-structured alloys (fcc-Ir0.50Pt0.50, fcc-Rh0.66Pt0.33 and fcc-Rh0.50Pd0.50) were prepared from [Ir(NH3)5Cl][PtCl6], [Ir(NH3)5Cl][PtBr6], [Rh(NH3)5Cl]2[PtCl6]Cl2 and [Rh(NH3)5Cl][PdCl4]·H2O, respectively, as single-source precursors. All alloys were prepared by thermal decomposition in gaseous hydrogen flow below 800 °C. Fcc-Ir0.50Pt0.50 and fcc-Rh0.50Pd0.50 correspond to miscibility gaps on binary metallic phase diagrams and can be considered as metastable alloys. Detailed comparison of [Ir(NH3)5Cl][PtCl6] and [Ir(NH3)5Cl][PtBr6] crystal structures suggests that two isoformular salts are not isostructural. In [Ir(NH3)5Cl][PtBr6], specific Br…Br interactions are responsible for a crystal structure arrangement. Room temperature compressibility of fcc-Ir0.50Pt0.50, fcc-Rh0.66Pt0.33 and fcc-Rh0.50Pd0.50 has been investigated up to 50 GPa in diamond anvil cells. All investigated fcc-structured binary alloys are stable under compression. Atomic volumes and bulk moduli show good agreement with ideal solutions model. For fcc-Ir0.50Pt0.50, V0/Z = 14.597(6) Å3·atom-1, B0 = 321(6) GPa and B0' = 6(1); for fcc-Rh0.66Pt0.33, V0/Z = 14.211(3) Å3·atom-1, B0 =259(1) GPa and B0' = 6.66(9) and for fcc-Rh0.50Pd0.50, V0/Z = 14.18(2) Å3·atom-1, B0 =223(4) GPa and B0' = 5.0(3).
Keywords: high-pressure; platinum group metals; refractory alloys; single-source precursors.