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Comportamiento crítico de láminas ferromagnéticas ultradelgadas = critical behaviour of ferromagnetic thin films / Santiago Alberto Pighín.

Por: Colaborador(es): Detalles de publicación: [S.l. : s.n. ] , 2009.Descripción: 151 páginas : ilustraciones; 30 cmTema(s): Recursos en línea: Disponible en líneaNota de disertación: Tesis (Doctor en Física)--Universidad Nacional de Córdoba. Facultad de Matemática, Astronomía y Física, 2009. Resumen: Las láminas ferromagnéticas ultradelgadas son sistemas magnéticos caracterizados por una fuerte anisotropía uniaxial producto del confinamiento del sistema en una de sus direcciones. Ésta favorece el alineamiento de los momentos magnéticos de los átomos perpendicular al plano de la lámina. El orden magnético de estos sistemas es de gran complejidad debido a la competencia entre las interacciones de intercambio y dipolar magnética a diferente escala espacial, además de la presencia de anisotropía. En el presente trabajo se propone un modelo de espines clásicos en donde se tiene en cuenta la interacción de intercambio (responsable del ordenamiento ferromagnético), anisotrópica (responsable de los ejes de fácil magnetización) y dipolar magnética (responsable de la generación de dominios magnéticos) para explicar la fenomenología.Resumen: Ferromagnetic ultrathin films are characterized by a strong uniaxial anisotropy due to the presence of an interface. This may favor a perpendicular alignment of the magnetic moments within the film. An example of this system is the film obtained by the deposition of Fe on a Cu substrate. Competition between the short-range exchange interaction and long-range dipolar interaction plus the action of anisotropy generate complex magnetic order. Thin films magnetic properties are strongly dependent on preparation conditions, thickness and temperature. At low temperatures, the system presents stripes, characterized by a modulation of the perpendicular magnetization in one direction only. When the temperature is increased, the stripes become narrower up to a transition into a ferromagnetic in-plane state or to a disordered state depending on experimental parameters. The disordering process can be mediated by two disordered phases, the nematic, with π/2 rotational simetry, and the tetragonal liquid, with π/4 rotational simetry. In the first part, we study the thin-films magnetic properties in the limit of high anisotropy, where the system is described by an Ising with short and long range interactions. We present a detailed calculation of the (δ,T) phase diagram, δ being the ratio between exchange and dipolar interaction intensities and T the temperature. We compare the results of both mean field approximation and Monte Carlo numerical simulations in the region of low values of δ. We found that, in the regions of the phase diagram where Monte Carlo simulations display nematic order, the mean field approximation predicts hybrid solutions composed by stripes of different widths. Another remarkable qualitative difference between both calculations is the absence, in this region of the Monte Carlo phase diagram, of the temperature dependency of the equilibrium stripe width predicted by the mean field approximation. In the second part, we propose a Heisenberg model to account for the behavior at intermediate anisotropies. We calculate the complete zero temperature (δ,η) phase diagram, η being the ratio between anisotropy and dipolar interaction intensities. Increasing the value of η through the reorientation phase transition we find three different stripes solutions: a canted phase, with nonzero in-plane magnetization within the domains; a saturated phase, characterized by zero in-plane magnetization within the domains and nonzero within the domains walls; and Ising stripes, with zero in-plane magnetization and sharp walls. We also present a detailed calculation of the (T,η) phase diagram with δ = 6. We find that the limit of high η values is consistent with the results obtained with the Ising model. We observe the reorientation phase transition and stripe width dependence with temperature. The phase diagram presents a scaling law and can be extrapolated to arbitrary values of δ, obtaining a good agreement with experiment. We find that the mechanism mediating stripe width transitions is the dislocation dynamic. This dynamic becomes slower at high η values. Finally, we simulate wedges appreciating the same phenomenology as experimental systems.
Etiquetas de esta biblioteca: No hay etiquetas de esta biblioteca para este título.
Existencias
Tipo de ítem Biblioteca actual Signatura Copia número Estado Notas Fecha de vencimiento Código de barras Reserva de ítems
Tesis de Doctorado Tesis de Doctorado FaMAF Vitrina T F PIG 1 Disponible 19848
Tesis de Doctorado Tesis de Doctorado FaMAF Secc. Tesis y Trabajos especiales Tesis Doctorado Física CAJA 16 - 19849 2 Disponible Disponible también en línea 19849
Total de reservas: 0

Tesis (Doctor en Física)--Universidad Nacional de Córdoba. Facultad de Matemática, Astronomía y Física, 2009.

Incuye referencias bibliográficas: p. 145-151.

Las láminas ferromagnéticas ultradelgadas son sistemas magnéticos caracterizados por una fuerte anisotropía uniaxial producto del confinamiento del sistema en una de sus direcciones. Ésta favorece el alineamiento de los momentos magnéticos de los átomos perpendicular al plano de la lámina. El orden magnético de estos sistemas es de gran complejidad debido a la competencia entre las interacciones de intercambio y dipolar magnética a diferente escala espacial, además de la presencia de anisotropía.
En el presente trabajo se propone un modelo de espines clásicos en donde se tiene en cuenta la interacción de intercambio (responsable del ordenamiento ferromagnético), anisotrópica (responsable de los ejes de fácil magnetización) y dipolar magnética (responsable de la generación de dominios magnéticos) para explicar la fenomenología.

Ferromagnetic ultrathin films are characterized by a strong uniaxial anisotropy due to the
presence of an interface. This may favor a perpendicular alignment of the magnetic moments within
the film. An example of this system is the film obtained by the deposition of Fe on a Cu substrate.
Competition between the short-range exchange interaction and long-range dipolar interaction plus
the action of anisotropy generate complex magnetic order. Thin films magnetic properties are
strongly dependent on preparation conditions, thickness and temperature. At low temperatures,
the system presents stripes, characterized by a modulation of the perpendicular magnetization
in one direction only. When the temperature is increased, the stripes become narrower up to a
transition into a ferromagnetic in-plane state or to a disordered state depending on experimental
parameters. The disordering process can be mediated by two disordered phases, the nematic, with
π/2 rotational simetry, and the tetragonal liquid, with π/4 rotational simetry.
In the first part, we study the thin-films magnetic properties in the limit of high anisotropy,
where the system is described by an Ising with short and long range interactions. We present
a detailed calculation of the (δ,T) phase diagram, δ being the ratio between exchange and dipolar interaction intensities and T the temperature. We compare the results of both mean field
approximation and Monte Carlo numerical simulations in the region of low values of δ. We found
that, in the regions of the phase diagram where Monte Carlo simulations display nematic order,
the mean field approximation predicts hybrid solutions composed by stripes of different widths.
Another remarkable qualitative difference between both calculations is the absence, in this region
of the Monte Carlo phase diagram, of the temperature dependency of the equilibrium stripe width
predicted by the mean field approximation.
In the second part, we propose a Heisenberg model to account for the behavior at intermediate anisotropies. We calculate the complete zero temperature (δ,η) phase diagram, η being the
ratio between anisotropy and dipolar interaction intensities. Increasing the value of η through the
reorientation phase transition we find three different stripes solutions: a canted phase, with nonzero in-plane magnetization within the domains; a saturated phase, characterized by zero in-plane
magnetization within the domains and nonzero within the domains walls; and Ising stripes, with
zero in-plane magnetization and sharp walls.
We also present a detailed calculation of the (T,η) phase diagram with δ = 6. We find that the
limit of high η values is consistent with the results obtained with the Ising model. We observe the
reorientation phase transition and stripe width dependence with temperature. The phase diagram
presents a scaling law and can be extrapolated to arbitrary values of δ, obtaining a good agreement
with experiment. We find that the mechanism mediating stripe width transitions is the dislocation
dynamic. This dynamic becomes slower at high η values. Finally, we simulate wedges appreciating
the same phenomenology as experimental systems.

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