Iron doped gold cluster nanomagnets: ab initio determination of barriers for demagnetization

Abstract

Magnetic properties of small- and nano-sized iron doped gold clusters are calculated at the level of second order multireference perturbation theory. We first assess the methodology for small Au₆Fe and Au₇Fe clusters, which are representative of even and odd electron count systems. We find that larger active spaces are needed for the odd electron count system, Au₇Fe, which exhibits isotropic magnetization behaviour. On the other hand, the even electron count system, Au₆Fe, exhibits strong axial magnetic anisotropy. We then apply this methodology to the tetrahedral and truncated pyramidal nano-sized Au₁₉Fe (with S = 3/2) and Au₁₈Fe (with S = 2) clusters. We find that face substitutions result in the most stable structures, followed by edge and corner substitutions. However, for Au₁₈Fe, corner substitution results in strong magnetic anisotropy and a large barrier for demagnetization while face substitution does not. Thus, although corner and face substituted Au₁₈Fe have the same spin, only corner substituted Au₁₈Fe can act as a single nanoparticle magnet.