Critical behavior and magnetic entropy change of skyrmion host Co7Zn8Mn5

Abstract

Abstract The magnetic properties of a β-Mn-type alloy Co7Zn8Mn5, which is a chiral magnet hosting skyrmion phase, are comprehensively investigated, exhibiting a ferromagnetic transition around 184 K and a spin freezing near 20 K. The generated Rhodes–Wolfarth ratio equals 1.10, which indicates a weak itinerant character of the ferromagnetism in Co7Zn8Mn5. The spin dynamics of the spin freezing agrees with the universal scaling law of critical slowing down with τ 0 = 1.7 × 10−5 s, T g = 20.2 K, and zν = 3.92. Critical exponents β = 0.423(1) and γ = 1.366(4) are deduced by the modified Arrott plot, whereas δ = 4.22(2) is obtained by a critical isotherm analysis. The validity of the deduced critical exponents is verified by the Widom scaling relation and the scaling hypothesis. The boundary between the first-order and the second-order phase transition is evaluated by a scaling analysis. The magnetic interaction, obtained by a renormalization group theory, decays with distance r as J(r) ≈ r −4.9, lying between the mean-field model and the 3D Heisenberg model. The analyses on critical behavior could shed new light on the origin of ferromagnetism and topological Hall effect. Moreover, the magnetic entropy change −ΔS M exhibits a maximal value around T C, and the peak position gradually raises with an increasing fields, eliminating the mean-field model. The − Δ S M max features a power-law behavior with n > 2/3, excluding any universal standard models of ferromagnetism. The −ΔS M(T, H) plots can be scaled into a universal curve, further verifying the reliability and accuracy of the yielded critical exponents.