Abstract
We explore the coherent dynamics in a small network of three coupled parametric oscillators and demonstrate the effect of frustration on the persistent beating between them. Since a single-mode parametric oscillator represents an analogue of a classical Ising spin, networks of coupled parametric oscillators are considered as simulators of Ising spin models, aiming to efficiently calculate the ground state of an Ising network—a computationally hard problem. However, the coherent dynamics of coupled parametric oscillators can be considerably richer than that of Ising spins, depending on the nature of the coupling between them (energy preserving or dissipative), as was recently shown for two coupled parametric oscillators. In particular, when the energy-preserving coupling is dominant, the system displays everlasting coherent beats, transcending the Ising description. Here, we extend these findings to three coupled parametric oscillators, focussing in particular on the effect of frustration of the dissipative coupling. We theoretically analyse the dynamics using coupled nonlinear Mathieu’s equations, and corroborate our theoretical findings by a numerical simulation that closely mimics the dynamics of the system in an actual experiment. Our main finding is that frustration drastically modifies the dynamics. While in the absence of frustration the system is analogous to the two-oscillator case, frustration reverses the role of the coupling completely, and beats are found for small energy-preserving couplings.
Highlights
Parametric oscillators are a viable experimental platform to study the physics of time crystals, i.e., systems that can spontaneously break time translational symmetry [1, 2]
This new type of time crystals, dubbed Floquet time crystals, accounts for the fact that, under certain conditions, a periodically-driven system can break the discrete time translational symmetry enforced by the external drive [8,9,10,11,12,13,14,15,16,17,18]: Instead of merely following the external drive, the system undergoes a periodic motion at a frequency that is different from that of the drive
We analyzed the behaviour of three coupled degenerate parametric oscillators - the minimal case to study nontrivial coupling and connectivity effects
Summary
Parametric oscillators are a viable experimental platform to study the physics of time crystals, i.e., systems that can spontaneously break time translational symmetry [1, 2]. Following Wilczek’s original idea, it was understood that time crystals can be realized out of equilibrium, in periodically-driven system, referred to as Floquet systems. This new type of time crystals, dubbed Floquet time crystals, accounts for the fact that, under certain conditions, a periodically-driven system can break the discrete time translational symmetry enforced by the external drive [8,9,10,11,12,13,14,15,16,17,18]: Instead of merely following the external drive, the system undergoes a periodic motion at a frequency that is different from that of the drive This new type of time crystals, dubbed Floquet time crystals, accounts for the fact that, under certain conditions, a periodically-driven system can break the discrete time translational symmetry enforced by the external drive [8,9,10,11,12,13,14,15,16,17,18]: Instead of merely following the external drive, the system undergoes a periodic motion at a frequency that is different from that of the drive (see ref. [1] for a review)
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