Abstract
The use of low-dimensional objects in the field of cavity optomechanics is limited by their low scattering cross section compared with the size of the optical cavity mode. Fiber-based Fabry-Perot microcavities can feature tiny mode cross sections and still maintain a high finesse, boosting the light-matter interaction and thus enabling the sensitive detection of the displacement of minute objects. Here we present such an ultrasensitive microcavity setup with the highest finesse reported so far in loaded fiber cavities, $\mathcal{F}=195\phantom{\rule{0.1em}{0ex}}000$. We are able to position-tune the static optomechanical coupling to a silicon nitride membrane stripe, reaching frequency pull parameters of up to $\ensuremath{\mid}G/2\ensuremath{\pi}\ensuremath{\mid}=1\phantom{\rule{0.2em}{0ex}}\mathrm{GHz}\phantom{\rule{0.1em}{0ex}}{\mathrm{nm}}^{\ensuremath{-}1}$. We also demonstrate radiation pressure backaction in the regime of an ultrahigh finesse up to $\mathcal{F}=165\phantom{\rule{0.1em}{0ex}}000$.
Highlights
The prospering field of cavity optomechanics [1] studies the coupling between the vibrations of a macroscopic mechanical object and the mode of an electromagnetic cavity
The use of low-dimensional objects in the field of cavity optomechanics is limited by their low scattering cross section compared with the size of the optical cavity mode
We present a proof-of-principle demonstration of the fiber-based Fabry-Perot microcavities (FFPCs) platform, demonstrating radiation pressure backaction using a free-standing stoichiometric silicon nitride (Si3N4) membrane stripe which is inserted into the cavity
Summary
The prospering field of cavity optomechanics [1] studies the coupling between the vibrations of a macroscopic mechanical object and the mode of an electromagnetic cavity. Possible applications range from exploring quantum signatures of macroscopic objects [2,3], over generating quantum states of light and matter [4,5,6], to realizing nonreciprocal devices [7,8] or acceleration or force sensors [9,10,11] Those applications are enabled by the extreme detection sensitivities of optomechanical systems [12] and often enhanced by minimal thermally induced decoherence at cryogenic temperatures or via reservoir engineering [13,14]. We introduce a platform for cavity optomechanics that is optimized for ultrasensitive optical detection of single-digit nanometer-size mechanical objects This is achieved with a FFPC that features a small mode cross section while maintaining the highest finesse reported so far in loaded FFPCs, exceeding that of the ground-breaking work in Ref. CNTs are discussed as one possible path towards quantum optomechanics at room temperature [32]
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