Evidence for structural damping in a high-stress silicon nitride nanobeam and its implications for quantum optomechanics
2017; Elsevier BV; Volume: 382; Issue: 33 Linguagem: Inglês
10.1016/j.physleta.2017.05.046
ISSN1873-2429
AutoresSergey A. Fedorov, Vivishek Sudhir, Ryan Schilling, H. Schütz, Dalziel J. Wilson, Tobias J. Kippenberg,
Tópico(s)Advanced MEMS and NEMS Technologies
ResumoWe resolve the thermal motion of a high-stress silicon nitride nanobeam at frequencies far below its fundamental flexural resonance (3.4 MHz) using cavity-enhanced optical interferometry. Over two decades, the displacement spectrum is well-modeled by that of a damped harmonic oscillator driven by a $1/f$ thermal force, suggesting that the loss angle of the beam material is frequency-independent. The inferred loss angle at 3.4 MHz, $\phi = 4.5\cdot 10^{-6}$, agrees well with the quality factor ($Q$) of the fundamental beam mode ($\phi = Q^{-1}$). In conjunction with $Q$ measurements made on higher order flexural modes, and accounting for the mode dependence of stress-induced loss dilution, we find that the intrinsic (undiluted) loss angle of the beam changes by less than a factor of 2 between 50 kHz and 50 MHz. We discuss the impact of such "structural damping" on experiments in quantum optomechanics, in which the thermal force acting on a mechanical oscillator coupled to an optical cavity is overwhelmed by radiation pressure shot noise. As an illustration, we show that structural damping reduces the bandwidth of ponderomotive squeezing.
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