Tailoring properties of Heusler alloys by elemental substitution and electron counting: (Co2-αMnα)FeGe, Co2(Fe1-βMnβ)Ge, and (Co2-αFeα)MnGe

Abstract

Rational material design by elemental substitution is useful in tailoring materials to have desirable properties. Here we consider three non-equivalent substitutional series based on Co2FeGe, viz; (Co2-αMnα)FeGe, Co2(Fe1-βMnβ)Ge, (Co2-αFeα)MnGe (0\!\!α\!\!2, 0\!\!β\!\!1), and study how material properties evolve with the interchange of Mn, Fe, and Co in Co2FeGe. In all three schemes, single-phase compounds can be obtained over a wide range of compositions: 0.125 < α < 1.375 for (Co2-αMnα)FeGe, 0 \!\! β \!\! 1 for Co2(Fe1-βMnβ)Ge, and 0 \!<\! α \!<\! 1.50 for (Co2-αFeα)MnGe. All the single-phase compounds crystallise in fcc structure with chemical ordering consistent with the ``4-2'' rule of Butler et al. The compounds are soft ferromagnets with low temperature saturation magnetisation agreeing with the Slater-Pauling rule. Very high Curie temperatures are measured, with values up to 1000 K for lower Mn concentrations. First principle calculations indicate, in the most stable atomic configuration, Mn prefers sharing sublattice with Ge, also consistent with the 4-2 rule. The calculations further predict half-metallic behaviour for (Co1.625Mn0.375)FeGe, while finding other compositions to be nearly half-metallic. Upon comparing the results of the three series, it is found that single-phase alloys occur for a specific range of valence electrons per unit cell (\!28.5\!-\!29.75), and that even for multi-phase samples the structural, magnetic, and electronic properties depend primarily on the number of valence electrons and not on the specific substitution scheme employed.