Free energy of twisting spins in Mn3Sn

The magnetic free energy is usually quadratic in the magnetic field and depends on the mutual orientation of the magnetic field and the crystalline axes. Tiny in magnitude, this magnetocrystalline anisotropy energy (MAE) is nevertheless indispensable for the existence of permanent magnets. Here, we show that in Mn3Sn, a noncollinear antiferromagnet that has attracted much attention following the discovery of its large anomalous Hall effect, the free energy of the spins has superquadratic components, which drive the MAE. We experimentally demonstrate that the thermodynamic free energy includes terms odd in the magnetic field [F(H-3) + F(H-5)] and generating sixfold and 12-fold angular oscillations in the torque response. We show that they are quantitatively explained by theory, which can be used to quantify relevant energy scales (Heisenberg, Dzyaloshinskii-Moriya, Zeeman, and single-ion anisotropy) of the system. Based on the theory, we conclude that in contrast to common magnets, what drives the MAE in Mn3Sn is the field-induced deformation of the spin texture.

Automated summary

The magnetic free energy in Mn3Sn, a noncollinear antiferromagnet, has superquadratic components, which drive the magnetocrystalline anisotropy energy (MAE). Experimental and theoretical analyses demonstrate the contributions of odd terms in the magnetic field and the resulting angular oscillations in torque response. The deformation of the spin texture induced by the magnetic field is found to be the driving force behind the MAE in Mn3Sn.