Ab initio determination of magnetic ground state of pyrochlore Y2Mn2O7

Abstract

There are two discrepant experimental results on the magnetic ground state of Y2Mn2O7, one study proposes a spin glass state, while another introduces the material as a ferromagnet. In this study, we attempt to resolve this issue by employing density functional theory and Monte Carlo simulations. We derive different spin models by varying the Hubbard U parameter in ab initio GGA+U calculations. For the most range of Hubbard U, We obtain that the leading terms in the spin Hamiltonian are bi-quadratic and the nearest neighbor Heisenberg exchange interactions. By comparing Monte Carlo simulations of these models with the experiments, we find a ferromagnetic ground state for Y2Mn2O7 as the most compatible with experiments. We also consider Y2Mo2O7 as a prototype of the defect-free pyrochlore system with spin-glass behavior and compare it with Y2Mn2O7. The orbital degrees of freedom are considered as a leading factor in converting a defect-free pyrochlore such as Y2Mn2O7 to a spin glass system. By changing the d orbital occupations of Mo atoms, our GGA+U calculations for Y2Mo2O7 indicate many nearly degenerate states with different d orbital orientations which reveals d orbital degrees of freedom in this material. While for Y2Mn2O7, we find a single ground state with a fixed orbital orientation. Consequently, all of our ab initio approaches confirm Y2Mn2O7 as a ferromagnetic system.