Noncontact friction in ultracoherent nanomechanical resonators near dielectric materials

• URL: http://arxiv.org/abs/2509.10237v1
• Date: Fri, 12 Sep 2025 13:31:38 GMT
• Title: Noncontact friction in ultracoherent nanomechanical resonators near dielectric materials
• Authors: Amirali Arabmoheghi, Alessio Zicoschi, Guillermo Arregui, Mohammad J. Bereyhi, Yi Xia, Nils J. Engelsen, Tobias J. Kippenberg,
• Abstract summary: Micro- and nanomechanical resonators are emerging as promising platforms for quantum technologies.<n>We report a novel dissipation mechanism that occurs in ultracoherent nanomechanical oscillators caused by the presence of nearby dielectrics.<n>Our findings provide insights into limitations on the integration of ultracoherent nanomechanical resonators.
• Score: 1.840562129212051
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Micro- and nanomechanical resonators are emerging as promising platforms for quantum technologies, precision sensors and fundamental science experiments. To utilize these devices for force sensing or quantum optomechanics, they must be brought in close proximity with other systems for functionalization or efficient readout. Improved understanding of the loss mechanisms in nanomechanical resonators, specifically the advent of dissipation dilution, has led to the development of resonators with unprecedented coherence properties. The mechanical quality factors of this new class of ultracoherent micro- and nanomechanical oscillators can now exceed 1 billion at room temperature, setting their force sensitivities below 1 $\mathrm{aN}/\sqrt{\mathrm{Hz}}$, surpassing those of the state-of-the-art atomic force microscopes (AFMs). Given this new regime of sensitivity, an intriguing question is whether the proximity of other materials hinders mechanical coherence. Here we show: it does. We report a novel dissipation mechanism that occurs in ultracoherent nanomechanical oscillators caused by the presence of nearby dielectrics. By studying the parameter scaling of the effect, we show that the mechanism is more severe for low-frequency mechanical modes and that it is due to dielectric loss within the materials caused by the motion of a resonator which carries static charges. Our observations are consistent with the noncontact friction (NCF) observed in AFMs. Our findings provide insights into limitations on the integration of ultracoherent nanomechanical resonators and highlight the adverse effects of charged defects in these systems.

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