Ferromagnetic resonance frequency increase and resonance line broadening of a ferromagnetic Fe―Co―Hf―N film with in-plane uniaxial anisotropy by high-frequency field perturbation

Soft ferromagnetic Fe-Co-Hf-N films, produced by reactive r.f. magnetron sputtering, are useful to study the ferromagnetic resonance (FMR) by means of frequency domain permeability measurements up to the GHz range. Films with the composition Fe(33)Co(43)Hf(10)N(14) exhibit a saturation polarisation...

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Veröffentlicht in:	Journal of magnetism and magnetic materials 2013-11, Vol.345, p.36-40
Hauptverfasser:	SEEMANN, K, LEISTE, H, KRÜGER, K
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Sprache:	eng
Schlagworte:	Anisotropy Condensed matter: electronic structure, electrical, magnetic, and optical properties Differential equations Exact sciences and technology Ferromagnetic, antiferromagnetic, and ferrimagnetic resonances spin-wave resonance Magnetic fields Magnetic moment Magnetic permeability Magnetic resonance Magnetic resonances and relaxations in condensed matter, mössbauer effect Perturbation Physics Resonance lines
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creator	SEEMANN, K LEISTE, H KRÜGER, K
description	Soft ferromagnetic Fe-Co-Hf-N films, produced by reactive r.f. magnetron sputtering, are useful to study the ferromagnetic resonance (FMR) by means of frequency domain permeability measurements up to the GHz range. Films with the composition Fe(33)Co(43)Hf(10)N(14) exhibit a saturation polarisation J(s) of around 1.35 T. They are consequently considered as being uniformly magnetised due to an in-plane uniaxial anisotropy of approximately ( mu o)H( mu )=4.5 m T after annealing them, e.g., at 400 degree C in a static magnetic field for 1 h. Being exposed to a high-frequency field, the precession of magnetic moments leads to a marked frequency-dependent permeability with a sharp Lorentzian shaped imaginary part at around 2.33 GHz (natural resonance peak), which is in a very good agreement with the modified Landau-Lifschitz-Gilbert (LLC) differential equation. A slightly increased FMR frequency and a clear increase in the resonance line broadening due to an increase of the exciting high-frequency power (1-25.1 mW), considered as an additional perturbation of the precessing system of magnetic moments, could be discovered. By solving the homogenous LLC differential equation with respect to the in-plane uniaxial anisotropy, it was revealed that the high-frequency field perturbation impacts the resonance peak position /fmr and resonance line broadening phi f(FMR) characterised by a completed damping parameter alpha = alpha (eff)+ phi a. Adapted from this result, the increase in f(FMR) and decrease in lifetime of the excited level of magnetic moments associated with A/fmr, similar to a spin-V(2) particle in a static magnetic field, was theoretically elaborated as well as compared with experimental data.
doi_str_mv	10.1016/j.jmmm.2013.06.003
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Films with the composition Fe(33)Co(43)Hf(10)N(14) exhibit a saturation polarisation J(s) of around 1.35 T. They are consequently considered as being uniformly magnetised due to an in-plane uniaxial anisotropy of approximately ( mu o)H( mu )=4.5 m T after annealing them, e.g., at 400 degree C in a static magnetic field for 1 h. Being exposed to a high-frequency field, the precession of magnetic moments leads to a marked frequency-dependent permeability with a sharp Lorentzian shaped imaginary part at around 2.33 GHz (natural resonance peak), which is in a very good agreement with the modified Landau-Lifschitz-Gilbert (LLC) differential equation. A slightly increased FMR frequency and a clear increase in the resonance line broadening due to an increase of the exciting high-frequency power (1-25.1 mW), considered as an additional perturbation of the precessing system of magnetic moments, could be discovered. By solving the homogenous LLC differential equation with respect to the in-plane uniaxial anisotropy, it was revealed that the high-frequency field perturbation impacts the resonance peak position /fmr and resonance line broadening phi f(FMR) characterised by a completed damping parameter alpha = alpha (eff)+ phi a. 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Films with the composition Fe(33)Co(43)Hf(10)N(14) exhibit a saturation polarisation J(s) of around 1.35 T. They are consequently considered as being uniformly magnetised due to an in-plane uniaxial anisotropy of approximately ( mu o)H( mu )=4.5 m T after annealing them, e.g., at 400 degree C in a static magnetic field for 1 h. Being exposed to a high-frequency field, the precession of magnetic moments leads to a marked frequency-dependent permeability with a sharp Lorentzian shaped imaginary part at around 2.33 GHz (natural resonance peak), which is in a very good agreement with the modified Landau-Lifschitz-Gilbert (LLC) differential equation. A slightly increased FMR frequency and a clear increase in the resonance line broadening due to an increase of the exciting high-frequency power (1-25.1 mW), considered as an additional perturbation of the precessing system of magnetic moments, could be discovered. By solving the homogenous LLC differential equation with respect to the in-plane uniaxial anisotropy, it was revealed that the high-frequency field perturbation impacts the resonance peak position /fmr and resonance line broadening phi f(FMR) characterised by a completed damping parameter alpha = alpha (eff)+ phi a. 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Films with the composition Fe(33)Co(43)Hf(10)N(14) exhibit a saturation polarisation J(s) of around 1.35 T. They are consequently considered as being uniformly magnetised due to an in-plane uniaxial anisotropy of approximately ( mu o)H( mu )=4.5 m T after annealing them, e.g., at 400 degree C in a static magnetic field for 1 h. Being exposed to a high-frequency field, the precession of magnetic moments leads to a marked frequency-dependent permeability with a sharp Lorentzian shaped imaginary part at around 2.33 GHz (natural resonance peak), which is in a very good agreement with the modified Landau-Lifschitz-Gilbert (LLC) differential equation. A slightly increased FMR frequency and a clear increase in the resonance line broadening due to an increase of the exciting high-frequency power (1-25.1 mW), considered as an additional perturbation of the precessing system of magnetic moments, could be discovered. By solving the homogenous LLC differential equation with respect to the in-plane uniaxial anisotropy, it was revealed that the high-frequency field perturbation impacts the resonance peak position /fmr and resonance line broadening phi f(FMR) characterised by a completed damping parameter alpha = alpha (eff)+ phi a. Adapted from this result, the increase in f(FMR) and decrease in lifetime of the excited level of magnetic moments associated with A/fmr, similar to a spin-V(2) particle in a static magnetic field, was theoretically elaborated as well as compared with experimental data.</abstract><cop>Amsterdam</cop><pub>Elsevier</pub><doi>10.1016/j.jmmm.2013.06.003</doi><tpages>5</tpages></addata></record>
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subjects	Anisotropy Condensed matter: electronic structure, electrical, magnetic, and optical properties Differential equations Exact sciences and technology Ferromagnetic, antiferromagnetic, and ferrimagnetic resonances spin-wave resonance Magnetic fields Magnetic moment Magnetic permeability Magnetic resonance Magnetic resonances and relaxations in condensed matter, mössbauer effect Perturbation Physics Resonance lines
title	Ferromagnetic resonance frequency increase and resonance line broadening of a ferromagnetic Fe―Co―Hf―N film with in-plane uniaxial anisotropy by high-frequency field perturbation
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