Vortex fluctuations and freezing of dipolar-coupled granular moments in thin ferromagnetic films
Abstract
Below the Curie temperature Tc of a Heusler-alloy film, consisting of densely packed, but exchange-decoupled nanograins, the spontaneous magnetization Ms(T) and static in-plane susceptibility ||(T) increase very slowly signalizing a suppression of magnetization fluctuations. The unpredicted variation ||(T) ~ Gd2(T), where Gd ~ Ms2 is the intergranular dipolar coupling, and also the magnetic freezing observed in the dynamic susceptibility at lower temperatures is quantitatively reproduced by Monte Carlo (MC) simulations with 104 dipolar-coupled moments on a disordered triangular lattice. At high temperatures, the MC spin configurations clearly reveal a dense gas of local vortex structures, which at low temperatures condense in regions with stronger disorder. This vortex depletion upon decreasing temperature seems to be responsible for the observed increase of the magnetic relaxation time. For weak disorder, the temperature dependence of the MC vorticity and a singularity of the specific heat at Tv=1/2 Gd(Tv)/kB indicate a thermal transition from a vortex gas to a state with a single vortex center plus linear vortex structures.
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