Phosphorus is thought to be an important light element existing in planetary cores. The phosphorus abundance is evaluated to be ~0.20 wt% in the Earth’s core, and ~0.32 wt% in the Martian core. To fully understand its existence in planetary cores, structural and physical properties of iron-nickel phosphides should be investigated under high pressure and high temperature. (Fe,Ni)₃P-schreibersite is observed as a common accessory in the veinlet of iron and stony-iron meteorites, so that it is of significance to discuss and constrain the properties of planetary cores. The equation of state of a natural single-crystal schreibersite, Fe_2.15Ni_0.85P, has been studied up to ~50 GPa at room temperature in a diamond anvil cell using in situ synchrotron-radiation X-ray diffraction. The sample kept its tetragonal structure (I-4 ) up to the highest pressure with no observation of phase transition. Experimental results have shown that the magnetic collapse of Fe_2.15Ni_0.85P is weakened because of the substitution of nickel, leading to an isotropic axial compressibility. The pressure-volume data were fitted by the third-order Birch-Murnaghan equation of state, yielding K₀ = 184(4) GPa, K₀' = 4.1(2), V₀ = 365.9(1) ų. The density of Fe_2.15Ni_0.85P, along with several iron sulfides and iron phosphides has been calculated under relative pressure-temperature conditions of the Martian core. The comparison with that of γ-Fe and a density model of the Martian core evidences that nickel and phosphorus dopant would result in density reduction of iron sulfides, suggesting that (Fe,Ni)₃(S,P) might be a possible compound existing in the Martian core.