Your search keyword '"Baró MD"' showing total 3 results

1. Magnetic proximity effect features in antiferromagnetic/ferrimagnetic core-shell nanoparticles.

Author

Golosovsky IV, Salazar-Alvarez G, López-Ortega A, González MA, Sort J, Estrader M, Suriñach S, Baró MD, and Nogués J

Abstract

A study of "inverted" core-shell, MnO/gamma-Mn(2)O(3), nanoparticles is presented. Crystal and magnetic structures and characteristic sizes have been determined by neutron diffraction for the antiferromagnetic core (MnO) and the ferrimagnetic shell (gamma-Mn(2)O(3)). Remarkably, while the MnO core is found to have a T_{N} not far from its bulk value, the magnetic order of the gamma-Mn(2)O(3) shell is stable far above T_{C}, exhibiting two characteristic temperatures, at T approximately 40 K [T_{C}(gamma-Mn(2)O(3))] and at T approximately 120 K [ approximately T_{N}(MnO)]. Magnetization measurements are consistent with these results. The stabilization of the shell moment up to T_{N} of the core can be tentatively attributed to core-shell exchange interactions, hinting at a possible magnetic proximity effect.

Published

2009

2. Imprinting vortices into antiferromagnets.

Author

Sort J, Buchanan KS, Novosad V, Hoffmann A, Salazar-Alvarez G, Bollero A, Baró MD, Dieny B, and Nogués J

Abstract

The effect of imprinting symmetric and displaced vortex structures into an antiferromagnetic material is investigated in micron-sized disks consisting of exchange coupled ferromagnetic-antiferromagnetic bilayers. The imprint of displaced vortices manifests itself by the occurrence of a new type of asymmetric hysteresis loops characterized by curved, reversible, central sections with nonzero remanent magnetization. Such an imprint is achieved by cooling the disks through the blocking temperature of the system in small fields. Micromagnetic simulations reveal that asymmetric vortexlike loops naturally result from the competition between the different energies involved in the system.

Published

2006

3. Magnetization reversal in submicron disks: exchange biased vortices.

Author

Sort J, Hoffmann A, Chung SH, Buchanan KS, Grimsditch M, Baró MD, Dieny B, and Nogués J

Abstract

Submicron, circular, ferromagnetic-antiferromagnetic dots exhibit different magnetization reversal mechanisms depending on the direction of the magnetic applied field. Shifted, constricted hysteresis loops, typical for vortex formation, are observed for fields along the exchange bias direction. However, for fields applied close to perpendicular to the exchange bias direction, magnetization reversal occurs via coherent rotation. Magnetic force microscopy imaging together with micromagnetic simulations are used to further clarify the different magnetic switching behaviors.

Published

2005