Surface spin-flop transition in a uniaxial antiferromagnetic Fe/Cr superlattice induced by a magnetic field of arbitrary direction

Abstract

We studied the transition between the antiferromagnetic and the surface spin-flop phases of a uniaxial antiferromagnetic [Fe(14 )/Cr(11 ] x20 superlattice. For external fields applied parallel to the in-plane easy axis, the layer-by-layer configuration, calculated in the framework of a mean-field one-dimensional model, was benchmarked against published polarized neutron reflectivity data. For an in-plane field H applied at an angle 0 with the easy axis, magnetometry shows that the magnetization M vanishes at H=0, then increases slowly with increasing H. At a critical value of H, a finite jump in M(H) is observed for <5 o, while a smooth increase of M vs H is found for >5 o. A dramatic increase in the full width at half maximum of the magnetic susceptibility is observed for 5 o. The phase diagram obtained from micromagnetic calculations displays a first-order transition to a surface spin-flop phase for low values, while the transition becomes continuous for greater than a critical angle, max ≈ 4.75 o. This is in fair agreement with the experimentally observed results.

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