Ferromagnetic Resonance - Theory and Applications 2013
DOI: 10.5772/56134
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Ferromagnetic Resonance

Abstract: The following information can be accessed with the help of such resonance experiments. (i) Electrical structure of point defects by looking at the absorption in a thin structure. (ii) The line width with the movement of spin or surroundings isn't changed. (iii) The distribution of the magnetic field in solid by looking at the of the resonance line position (chemical shift and etc.). (iv) Collective spin excitations. Ferromagnetic Resonance-Theory and Applications 2 The atoms of ferromagnetic coupling originate… Show more

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Cited by 26 publications
(16 citation statements)
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References 200 publications
(217 reference statements)
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“…Furthermore, the linear growth of H r with E implies an increasing negative surface spin density, which will give rise to a decrease of the effective damping, and more detectable, a sign transition in small α at the critical electric field. Taking the odd-parity of the imaginary part of the magnetic susceptibly and its relation to damping α 39 , we expect a phase transition close to the frequency of FMR, which is in line with the experimental observations. The nonmonotonic behavior of the effective Δ eff may be due to a nonlinear interplay of the higher order effects with nonlocal damping 22 , originating from the dissipative flow of nonequilibrium intralayer spin currents within the interface.…”
Section: Resultssupporting
confidence: 89%
See 1 more Smart Citation
“…Furthermore, the linear growth of H r with E implies an increasing negative surface spin density, which will give rise to a decrease of the effective damping, and more detectable, a sign transition in small α at the critical electric field. Taking the odd-parity of the imaginary part of the magnetic susceptibly and its relation to damping α 39 , we expect a phase transition close to the frequency of FMR, which is in line with the experimental observations. The nonmonotonic behavior of the effective Δ eff may be due to a nonlinear interplay of the higher order effects with nonlocal damping 22 , originating from the dissipative flow of nonequilibrium intralayer spin currents within the interface.…”
Section: Resultssupporting
confidence: 89%
“…For an insight into the electrical tuning of magnetic dynamics, we study the resonance spectra based on the phenomenological LLG equation, which has been widely used for interpreting and predicting vast experimental results of magnetic structures (See Ref. 39 and the supplementary ). We find…”
Section: Resultsmentioning
confidence: 99%
“…resonance is not resolved for Mn fractions above 0.5 % [24]. 5 % doped ZnS nano particles have the central sharp line at g = 2.002293, a sextet of relatively broad lines was observed at g = 2.0008 [25] and eight-line pattern in [26]. For nanoparticles, however, the ESR signal with the HF structure was resolved even for samples with 30 % Mn dopant [11].…”
Section: Epr Studiesmentioning
confidence: 94%
“…NiFe2O4 as ferrimagnetic materials are closely related with the resonance behaviour, which is strongly associated to magnetic materials. Ferromagnetic resonance, electron paramagnetic resonance, among others, are few phenomenons occur at varying frequencies [10], which compose the resonance behaviour of materials. X-band (8-12 GHz) is widely used in terrestrial wireless communication.…”
Section: Introductionmentioning
confidence: 99%