2019
DOI: 10.1002/adom.201901507
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Optomechanics of Chiral Dielectric Metasurfaces

Abstract: The coupling between electromagnetic fields and mechanical motion in micro‐ and nanostructured materials has recently produced intriguing fundamental physics, such as the observation of mesoscopic optomechanical phenomena in objects operating in the quantum regime. It is also yielding innovative device applications, for instance in the manipulation of the optical response of photonic elements. Following this concept, here it is shown that combining a nanostructured chiral metasurface with a semiconductor suspe… Show more

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Cited by 35 publications
(36 citation statements)
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“…, and w displacement components along x, y, and z directions, respectively, while the artificial displacement has been artificially exaggerated for visualization purposes. The mode resonant frequency has been found to be 372 kHz, in good agreement with independent characterization with a Laser Doppler Vibrometer [20].…”
Section: Device Design and Fabricationsupporting
confidence: 79%
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“…, and w displacement components along x, y, and z directions, respectively, while the artificial displacement has been artificially exaggerated for visualization purposes. The mode resonant frequency has been found to be 372 kHz, in good agreement with independent characterization with a Laser Doppler Vibrometer [20].…”
Section: Device Design and Fabricationsupporting
confidence: 79%
“…In particular, by using a chiral pattern for the metasurface definition, we show a dynamical manipulation of the output light polarization, which can be dynamically controlled along non-trivial paths on the Poincarè sphere. A detailed discussion of quantitave, single frequency polarization modulation at ∼400 kHz and, conversely, light polarimetry has been reported elsewhere [20]; in this article we show how the operation bandwidth of the device can be extended to about 1.4 MHz, exploiting the overdamping regime of the mechanical resonator at atmospheric pressure.…”
Section: Introductionsupporting
confidence: 55%
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“…Recent years have witnessed a renaissance in the investigation of micro and nanomechanical devices, pushed by the capabilities they gain when combined to photonic and/or electronic systems. Achievements such as zepto and yoctogram mass sensing [1][2][3], acceleration sensing as low as 10 μg Hz −1/2 [4], low power, light intensity [5][6][7] and, more recently, polarization [8] fast modulation are just a few examples of the technology enabled by opto and electromechanical nanosystems [9]. Following an avenue devoted to fundamental physics, these mescoscopic devices have rightfully entered the realm of quantum mechanics, inaugurated by the milestone achievement of ground-state cooling of the motion in micrometric sized optomechanical [10] and electromechanical [11] devices.…”
Section: Introductionmentioning
confidence: 99%
“…This additional degree of control over light allows quantum and classical applications, such as wavelength conversion between two distant optical frequencies [18][19][20][21] that can feature adiabatic quantum state transfer [22,23], non-demolition measurements [24], entanglement generation [25][26][27], nonreciprocal transport and optical routing [28][29][30][31][32]. For the large part, these proposals have been so far based on manipulating the scalar properties of photons, while their vector nature has only been recently pinpointed [33][34][35].…”
mentioning
confidence: 99%