Theory of Magnetocrystalline Anisotropy Energy for Wires and Corrals of Fe adatoms: A Non-Perturbative Theory
Abstract
The magnetocrystalline anisotropy energy Eanis for free-standing chains (quantum wires) and rings (quantum corrals) of Fe-adatoms N=(2...48) is determined using an electronic tight-binding theory. Treating spin-orbit coupling non-perturbatively, we analyze the relationship between the electronic structure of the Fe d-electrons and Eanis(nd), for both the chain and ring conformations. We find that Eanis(N) is larger for wires than for rings or infinite monolayers. Generally Eanis(nd) decreases in chains upon increasing N, while for rings Eanis(nd) is essentially independent of N. For increasing N, Eanis(nd) in corrals approaches the results for freestanding monolayers. Small rings exhibit clear odd-even oscillations of Eanis(N). Within our theoretical framework we are able to explain the experimentally observed oscillations of Eanis(nd) during film growth with a period of one monolayer. Finally, a generalization of Hund's third rule on spin-orbit coupling to itinerant ferromagnets is proposed.
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