Nonlinear spin dynamics induced by feedback under continuous Larmor frequency distributions

TL;DR

This paper investigates the complex nonlinear spin dynamics induced by feedback in systems with continuous distributions of Larmor frequencies, revealing stable limit cycles, quasi-periodic orbits, and chaos, with implications for precision measurement and quantum phenomena.

Contribution

It extends previous studies from discrete to continuous Larmor frequency distributions, analyzing the resulting nonlinear dynamics and stability conditions in spin systems.

Findings

Stable limit cycles, quasi-periodic orbits, and chaos are identified in the system.

The relation between synchronization frequency and magnetic field inhomogeneity is established.

The robustness of different dynamical phases against fluctuations is analyzed.

Abstract

Nonlinear spin dynamics are essential in exploring nonequilibrium quantum phenomena and have broad applications in precision measurement. Among these systems, the combination of a bias magnetic field and feedback mechanisms can induce self-sustained oscillations at the base Larmor frequency due to nonlinearity. These features have driven the development of single-species and multiple-species spin masers. The latter, with multiple discrete Larmor frequencies, provides significant advantages for precision measurement by mitigating uncertainties in precession frequencies due to long-term drifts in experimental conditions. The self-sustained oscillations of single-species and multiple-species spin masers correspond to limit cycles and quasi-periodic orbits of the stable nonlinear dynamics of the systems respectively; the correspondence is elucidated in a recent study on a related spin system featuring two discrete intrinsic Larmor frequencies under dual bias magnetic fields. Here, we extend the study to the case that the intrinsic Larmor frequencies of individual spins of the system, given rise to by an inhomogeneous bias magnetic field, form a continuum. We show that generically the stable dynamics of the system includes limit cycles, quasi-periodic orbits, and chaos. We establish the relation between the synchronization frequency of limit cycles and the field inhomogeneity and derive an equation determining the stability of limit cycles. Furthermore, detailed characteristics of different dynamical phases, especially the robustness of limit cycles and quasi-periodic orbits against experimental fluctuations, are discussed. Our findings not only encompass the case of discrete Larmor frequencies, but also provide crucial insights for precision measurement and the exploration of continuous time crystals and quasi-crystals.