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Paper detail

Frequency comb from a single driven nonlinear nanomechanical mode

Phononic frequency combs have been attracting an increasing attention both as a qualitatively new type of nonlinear phenomena in vibrational systems and from the point of view of applications. It is commonly believed that at least two modes must be involved in generating a comb. In this paper we demonstrate that a comb can be generated by a single nanomechanical mode driven by a resonant monochromatic drive. The comb emerges where the drive is still weak, so that the anharmonic part of the mode potential energy remains small. We relate the effect to a negative nonlinear friction induced by the resonant drive, which makes the vibrations at the drive frequency unstable. We directly map the trajectories of the emerging oscillations in the rotating frame and show how these oscillations lead to the frequency comb in the laboratory frame. The results go beyond nanomechanics and suggest a qualitatively new approach to generating tunable frequency combs in single-mode vibrational systems.

preprint2022arXivOpen access
J. S. OchsD. K. J. BonessG. RastelliM. SeitnerW. BelzigM. I. DykmanE. M. Weig
cond-mat.mes-hallphysics.opticsphysics.class-ph
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J. S. OchsD. K. J. BonessG. RastelliM. SeitnerW. BelzigM. I. DykmanE. M. Weig

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