Correlated anomalous phase diffusion of coupled phononic modes in a side-band driven resonator

TL;DR

This study explores how coupled phononic modes in a driven resonator exhibit correlated anomalous phase diffusion, revealing new aspects of discrete time-translation symmetry and potential for stable frequency standards.

Contribution

It provides the first experimental and theoretical analysis of phase diffusion and symmetry in coupled vibrational modes under parametric driving.

Findings

Phase fluctuations are nearly perfectly anti-correlated between modes.

Phase undergoes superlinear anomalous diffusion influenced by 1/f noise.

Feedback can stabilize oscillations for frequency standard applications.

Abstract

The dynamical backaction from a periodically driven optical or microwave cavity can reduce the damping of a mechanical resonator, leading to parametric instability accompanied by self-sustained oscillations. Fundamentally, the driving breaks the continuous time-translation symmetry and replaces it with the symmetry with respect to time translation by the driving period. This discrete symmetry should be reflected in the character of the oscillations. Here, we perform experimental and theoretical study of new aspects of the backaction and the discrete time-translation symmetry using a micromechanical resonator designed to have two nonlinearly coupled vibrational modes with strongly differing frequencies and decay rates. We find that self-sustained oscillations are induced not only in the low frequency mode as measured in previous experiments, but also in the high frequency mode. The vibration frequencies and amplitudes are determined by the system nonlinearity, which also leads to bistability and hysteresis. A remarkable consequence of the discrete time-translation symmetry is revealed by studying the vibration phases. We find that the phase fluctuations of the two modes are nearly perfectly anti-correlated. At the same time, in each mode the phase undergoes anomalous diffusion, where the time dependence of the phase variance follows a superlinear rather than the standard linear power law. Our analysis shows that the exponent of the power law is determined by the exponent of the 1/f-type intrinsic frequency noise of the resonator. We demonstrate the possibility of compensating for these fluctuations using a feedback scheme to generate stable oscillations that could prove useful in frequency standards and resonant detection.