Fragile balance of the exchange interactions in Mn1-xCoxGe compounds

Abstract

The magnetic system of the pseudobinary compound Mn1-xCoxGe has been studied using small-angle neutron scattering and SQUID-measurements. It is found that Mn1-xCoxGe orders magnetically at low temperatures in the whole concentration range of x ∈ [0 0.9]. Three different states of the magnetic structure have been found: a short-periodic helical state at x ≤ 0.45, a long-periodic helical state at 0.45 < x ≤ 0.8, and a ferromagnetic state at x 0.9. Taking into account that the relatively large helical wavevector k 1 nm-1 is characteristic for systems with mainly Ruderman-Kittel-Kasuya-Yoshida (RKKY) interaction, we suggest that the short-periodic helical structure at x ≤ 0.45 is based on an effective RKKY interaction. Also the decay of k with increasing x is ascribed to a reduction of the interaction between second nearest neighbors and, therefore, to an increase of the influence of the Dzyaloshinskiy-Moriya interaction (DMI). As a result of the competition between these two interactions the quantum phase transition from a long-range ordered (LRO) to a short-range ordered (SRO) helical structure has been observed upon increase of the Co-concentration at xc1 0.25. Further increase of x leads to the appearance of a double peak in the scattering profile at 0.45 < x < 0.7. The transition from a helical structure to a ferromagnetic state found at x = 0.9 is caused by the weakening of DMI as compared to the cubic anisotropy. In summary, the evolution of the magnetic structure of Mn1-xCoxGe with increasing x is an example of a continuous transition from a helical structure based on the effective RKKY interaction to a ferromagnetic structure passing through a helical structure based on DMI.