First-Principles Dynamical Coherent-Potential Approximation Approach to the Ferromagnetism of Fe, Co, and Ni

Magnetic properties of Fe, Co, and Ni at finite temperatures have been investigated on the basis of the first-principles dynamical coherent potential approximation (CPA) combined with the local density approximation (LDA) + U Hamiltonian in the tight-binding linear muffintin orbital (TB-LMTO) representation. The Hamiltonian includes the transverse spin fluctuation terms. Numerical calculations have been performed within the harmonic approximation with 4th-order dynamical corrections. Calculated single-particle densities of states in the ferromagnetic state indicate that the dynamical effects reduce the exchange splitting, suppress the band width of the quasi-particle state, and causes incoherent excitations corresponding the 6 eV satellites. Results of the magnetization vs temperature curves, paramagnetic spin susceptibilities, and the amplitudes of local moments are presented. Calculated Curie temperatures (T-C) are reported to be 1930K for Fe, 2550K for Co, and 620K for Ni; T-C for Fe and Co are overestimated by a factor of 1.8, while T-C in Ni agrees with the experimental result. Effective Bohr magneton numbers calculated from the inverse susceptibilities are 3.0 mu(B) (Fe), 3.0 mu(B) (Co), and 1.6 mu(B) (Ni), being in agreement with the experimental ones. Overestimate of T-C in Fe and Co is attributed to the neglects of the higher-order dynamical effects as well as the magnetic short range order.