Abstract

Introduction. Today, many research endeavors are devoted to the miniaturization of microwave sources. One of the promising approaches is the use of magnetic nanostructures (spintronics elements), providing a wide range of frequency tuning and low power consumption. The main disadvantage of spintronics generators (spintransfer nanoscillators ‒ STNO) is a low output power of generated oscillations (tens of nanowatts and less). A possible solution is to sum up the power of many STNOs in a mutual synchronization mode.Aim. The investigation of noise properties of two connected STNOs with identical and non-identical parameters in a phase synchronization mode.Materials and methods. A model was developed of two STNOs interconnected by spin waves taking into account thermal noises. Spectral power densities of the amplitude and phase noise were obtained by the method of effective linearization.Results. Dependencies were obtained in a general form for attenuation coefficients of the amplitude and phase fluctuations of noise sources for each STNO. Three cases of synchronization were considered: completely identical STNOs, two identical STNOs but with different oscillation frequencies, and two non-identical STNOs, differing in an allowance of self-excitation by frequencies and amplitudes of the oscillations. It was possible to obtain a gain in the amplitude and phase noise for two identical STNOs. In this case, an increase in the allowance of self-excitation led to a decrease in the level of phase and amplitude noise.Conclusion. This analysis of the attenuation coefficients for non-identical STNOs demonstrates the possibility of improving the noise properties of each of the generators. In this case, the best noise value is obtained for an STNO with greater stability in a stand-alone mode.

Highlights

  • Today, many research endeavors are devoted to the miniaturization of microwave sources

  • We study the effect of synchronization of two coupled spin-transfer nanoscillators (STNO) in phase synchronization mode on amplitude and phase noise

  • It is possible to obtain a gain in the level of amplitude and phase noise for two identical STNOs

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Summary

Introduction

Oscillation sources of microwave frequency range devices are based on either of the following: lumped elements (capacitors and inductors), delay lines, resonators on surface acoustic waves (SAWs), spin-wave devices, dielectric (including ceramic) circuits, waveguides, or other resonators [1]. Special attention has been given to solid state physics, where nanoscale spin-wave devices ‒ "spintronics" devices ‒ are studied. Such devices are spin-transfer nanoscillators (STNO), which are multilayer nanostructures, most often cylindrical, made up of alternating magnetic and nonmagnetic layers [2,3,4,5,6,7]. Where ci i 1, 2 are the complex amplitudes of the spin waves of the first and second STNO; i 0i Ni ci 2 is the dependence of the oscillation frequency on the amplitude ( 0i is the frequency of the ferromagnetic resonance of the ith STNO; Ni is the nonisochronism coefficient); i сi 2. The derivative of the complex amplitude (2) has the form: dсi dt dUi dt

Ui j av d
Conclusion

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