First-principles study of the electronic and magnetic properties of cubic GdCu compound

Abstract

The structural, electronic, and magnetic properties of bulk GdCu (CsCl-type) are investigated using spin density functional theory, where highly localized 4f orbitals are treated within LDA+U and GGA+U methods. The calculated magnetic ground state of GdCu using collinear as well as spin spiral calculations exhibits a C-type antiferromagnetic configuration representing a spin spiral propagation vector Q=2πa(12,12,0). The parameters of the effective Heisenberg Hamiltonian are evaluated from a self-consistent electronic structure and are used to determine the magnetic transition temperature. The estimated N\'eel temperature of the cubic GdCu using GGA+U and LDA+U density functionals within the mean field and random phase approximations are in good agreement with the experimentally measured values. In particular, the theoretical understanding of the experimentally observed core Gd 4f levels shifting in photoemission spectroscopy experiments is investigated in detail. By employing the self-consistent constrained random-phase approximation we determined the strength of the effective Coulomb interaction (Hubbard U) between localized 4f electrons. We find that, the shift of Gd-4f states in GdCu with respect to bulk Gd within DFT+U is sensitive to choice of lattice parameter. The calculations for 4f-level shifts using DFT+U methods as well as Hubbard-1 approximation are not consistent with the experimental findings.