First-principles calculation of the Gilbert damping parameter via the linear response formalism with application to magnetic transition-metals and alloys

Abstract

A method for the calculations of the Gilbert damping parameter α is presented, which based on the linear response formalism, has been implemented within the fully relativistic Korringa-Kohn-Rostoker band structure method in combination with the coherent potential approximation alloy theory. To account for thermal displacements of atoms as a scattering mechanism, an alloy-analogy model is introduced. This allows the determination of α for various types of materials, such as elemental magnetic systems and ordered magnetic compounds at finite temperature, as well as for disordered magnetic alloys at T = 0 K and above. The effects of spin-orbit coupling, chemical and temperature induced structural disorder are analyzed. Calculations have been performed for the 3d transition-metals bcc Fe, hcp Co, and fcc Ni, their binary alloys bcc Fe1-xCox, fcc Ni1-xFex, fcc Ni1-xCox and bcc Fe1-xVx, and for 5d impurities in transition-metal alloys. All results are in satisfying agreement with experiment.