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Magneto-optical study of the dynamic properties of magnetic nanostructures and nanostructured metamaterials
Flajšman, Lukáš ; Chumak, Andrii (oponent) ; Revelosona, Dafiné (oponent) ; Spousta, Jiří (vedoucí práce)
The magnonics is the novel research topic in magnetism concerned with the physics of spin waves. The magnonics has the potential to introduce novel devices for wave-based computing with low power consumption. During the fabrication process of the magnonic devices using common materials and fabrication techniques, we are left only with a minimum means of how to alter the inherent properties of the magnetic materials. This highly limits the usability or versatility of the structures. This work introduces a novel material to the magnonics. The unique and highly deterministic properties of the structures prepared by focused ion beam direct writing into the metastable iron layer are presented and partially exploited in a set of prototypical structures prepared in the system. The important parameters of the system are extracted from the measurement of the spin-wave dispersion by the means of the phase-resolved Brillouin light scattering method. The findings are supported by the micromagnetic simulations and by using the analytical models. Three sets of novel magnonic devices that exploit the unique properties of the system are presented and tested.
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Metastable iron thin films for magnetic metamaterials
Holobrádek, Jakub ; Man, Ondřej (oponent) ; Urbánek, Michal (vedoucí práce)
Magnetic nanostructures are widely investigated for applications in industrial and fundamental research thanks to their interesting properties. One of the concerned scientific disciplines is magnonics – a novel research topic in magnetism concerned with the physics of spin waves, which can be used for fabrication of novel devices for wave-based computing with low power consumption. Fabrication of magnonic structures by a focused ion beam (FIB) is an alternative method to the commonly used lithographic methods. The material used in this work -- metastable iron – is able to undergo an ion-beam-induced phase transformation from a paramagnetic fcc to a ferromagnetic bcc phase. One of the properties, which affect the spin-wave propagation, is magnetic anisotropy. This thesis presents the influence of UHV conditions during the deposition of the metastable iron film on the magnetic anisotropy of the structures fabricated via FIB into this film. We also investigate the relationship between FIB parameters, crystallographic properties of the resulting structures, and their magnetic anisotropy.
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Metastable iron thin films for magnetic metamaterials
Holobrádek, Jakub ; Man, Ondřej (oponent) ; Urbánek, Michal (vedoucí práce)
Magnetic nanostructures are widely investigated for applications in industrial and fundamental research thanks to their interesting properties. One of the concerned scientific disciplines is magnonics – a novel research topic in magnetism concerned with the physics of spin waves, which can be used for fabrication of novel devices for wave-based computing with low power consumption. Fabrication of magnonic structures by a focused ion beam (FIB) is an alternative method to the commonly used lithographic methods. The material used in this work -- metastable iron – is able to undergo an ion-beam-induced phase transformation from a paramagnetic fcc to a ferromagnetic bcc phase. One of the properties, which affect the spin-wave propagation, is magnetic anisotropy. This thesis presents the influence of UHV conditions during the deposition of the metastable iron film on the magnetic anisotropy of the structures fabricated via FIB into this film. We also investigate the relationship between FIB parameters, crystallographic properties of the resulting structures, and their magnetic anisotropy.
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Magneto-optical study of the dynamic properties of magnetic nanostructures and nanostructured metamaterials
Flajšman, Lukáš ; Chumak, Andrii (oponent) ; Revelosona, Dafiné (oponent) ; Spousta, Jiří (vedoucí práce)
The magnonics is the novel research topic in magnetism concerned with the physics of spin waves. The magnonics has the potential to introduce novel devices for wave-based computing with low power consumption. During the fabrication process of the magnonic devices using common materials and fabrication techniques, we are left only with a minimum means of how to alter the inherent properties of the magnetic materials. This highly limits the usability or versatility of the structures. This work introduces a novel material to the magnonics. The unique and highly deterministic properties of the structures prepared by focused ion beam direct writing into the metastable iron layer are presented and partially exploited in a set of prototypical structures prepared in the system. The important parameters of the system are extracted from the measurement of the spin-wave dispersion by the means of the phase-resolved Brillouin light scattering method. The findings are supported by the micromagnetic simulations and by using the analytical models. Three sets of novel magnonic devices that exploit the unique properties of the system are presented and tested.
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