T. J. Matcovich scite author profile

Calculations and measurements have been made of the shift of the ferromagnetic resonance frequency in the presence of excited magnons. The calculations were carried out by retaining terms in the Hamiltonian up to fourth order in the spin-wave variables and by treating these terms in a random phase approximation. The frequency shift depends linearly on the number of excited k = 0 and ky^O magnons, with a ^-dependent proportionality factor. Measurements of this shift therefore can be used to determine the magnon distribution at resonance, and such measurements have been used to study the effect of surface preparation of the sample on the magnon distribution. The results show considerable agreement with the surface pit model; namely, the linewidth and the number of k^O magnons increase with increased surface roughness, the surface-induced scattering from the £=0 mode occurs to a localized group of degenerate kp^O spin waves, and the effective wavelength of the spin wave to which scattering occurs increases with increased surface roughness. The data are not consistent with the theory that there is a rapid equilibration of the degenerate spin waves. The frequency shift was also observed at power levels above the critical value for the onset of nonlinearities. The results cannot be explained simply by invoking the instability of 0£ = O spin waves.Possible alternate explanations are offered.

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Low-power thin-film memory

Kriessman

Matcovich

Flannery

1964

IEEE Trans. Comm. Electron.

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Anisotropy Rotation in Thin Permalloy Films at Room Temperature

Matcovich

Korostoff

Schmeckenbecher

1961

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It has been observed that the magnetic anisotropy direction of certain thin Permalloy films prepared by the thermal decomposition of nickel and iron carbonyls can be rotated through 90 deg at room temperature by fields less than 10 oe. The experimental conditions under which these films were prepared suggest that this phenomenon is due to the presence of carbon. The relaxation time for the rotation of the anisotropy axis was calculated from the time dependence of the induction and found to be 10 msec. A simple model has been developed which relates the anisotropy rotation to specific domain wall configurations and to the establishment of a “directional order” among interstitial carbon atoms.

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Resonant Frequency Shift in Ellipsoidal Samples

Matcovich

Belson

Goldberg

1961

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Articles you may be interested inShifts of frequency and bandwidth of quartz crystal resonators coated with samples of finite lateral size A polished, ellipsoidal, single crystal, yttrium iron garnet sample with rotation axis along a [ 1ooJ direction and tJ.fl = 1.0 oe was prepared. X -band measurements of the microwave resonant frequency were made as a function of rf power. The resonant frequency was found to shift at the rate of 41 Mc/ w. The shift of the resonant frequenc), was related to the number of k:::110 magnons (" 0) and the number of k~O magnons ( Il k) by means of spin-wave theory. From this relation and the experimental data the value of 11 1.:/11 0 was determined to be 2.7.

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T. J. Matcovich

Laboratory Modeling of Bubble Propagation Systems

Ferromagnetic Resonance Frequency Shift in Yttrium Iron Garnet

Low-power thin-film memory

Anisotropy Rotation in Thin Permalloy Films at Room Temperature

Resonant Frequency Shift in Ellipsoidal Samples

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