Physical Review Research (Dec 2021)

Chaos in spin-torque oscillator with feedback circuit

  • Akira Kamimaki,
  • Tomoyuki Kubota,
  • Sumito Tsunegi,
  • Kohei Nakajima,
  • Tomohiro Taniguchi,
  • Julie Grollier,
  • Vincent Cros,
  • Kay Yakushiji,
  • Akio Fukushima,
  • Shinji Yuasa,
  • Hitoshi Kubota

DOI
https://doi.org/10.1103/PhysRevResearch.3.043216
Journal volume & issue
Vol. 3, no. 4
p. 043216

Abstract

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Excitation of chaotic magnetization dynamics in nanomagnets is of great interest because it bridges the condensed matter physics and nonlinear science and has a potential to emerging technologies such as neuromorphic computing. However, it has been difficult to observe and identify chaos in spintronics devices because the excitation of chaos requires dynamics in a large-dimensional phase space, according to the Poincaré-Bendixson theorem. An efficient way to overcome this issue is using feedback, which enables the dynamical degrees of freedom to be increased even in a single device. Here, we experimentally demonstrate the excitation of chaos in a vortex spin-torque oscillator by utilizing a feedback circuit. The radio-frequency current emitted by the oscillator flows in the feedback circuit and is converted into an oscillating magnetic field. The oscillating field generates a torque acting on the vortex and modulates its dynamics, resulting in chaotic dynamics which can be tuned by electrical means.