2011
DOI: 10.1038/nnano.2011.180
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Dynamic manipulation of nanomechanical resonators in the high-amplitude regime and non-volatile mechanical memory operation

Abstract: Classical and quantum dynamics of nanomechanical systems promise new applications in nanotechnology 18,19 and fundamental tests of quantum mechanics in mesoscopic objects 2,9 . Recent development of nanoscale electromechanical (NEMS) and optomechanical systems has enabled cooling of mechanical systems to their quantum ground state 7,8 , which brings the possibility of quantum information processing with mechanical devices 20,21 . On the other hand, for practical application at room temperature -such as signal… Show more

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Cited by 243 publications
(217 citation statements)
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“…Cavity optomechanical devices are inherently nonlinear mechanical systems 29 because the optomechanical interaction involves the intra-cavity field, which depends nonlinearly on the mechanical elements' position. Exploiting the nonlinear dynamics in cavity optomechanical systems will be especially important to applications that need to operate the devices in the high-amplitude regime, such as optomechanical oscillators 17,18 and optomechanical memory 19 . As can be seen from equation (1) In the small-amplitude regime, the nonlinear terms are insignificant and only the frequency down shift due to the optical spring k 1 can be observed as in Fig.…”
Section: Resultsmentioning
confidence: 99%
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“…Cavity optomechanical devices are inherently nonlinear mechanical systems 29 because the optomechanical interaction involves the intra-cavity field, which depends nonlinearly on the mechanical elements' position. Exploiting the nonlinear dynamics in cavity optomechanical systems will be especially important to applications that need to operate the devices in the high-amplitude regime, such as optomechanical oscillators 17,18 and optomechanical memory 19 . As can be seen from equation (1) In the small-amplitude regime, the nonlinear terms are insignificant and only the frequency down shift due to the optical spring k 1 can be observed as in Fig.…”
Section: Resultsmentioning
confidence: 99%
“…Research in cavity optomechanics exploits the dynamical interplay between the intra-cavity optical field and the mechanical motion of the device, leading to demonstrations of unprecedented phenomena including backaction cooling [10][11][12][13] , normal mode splitting 14 and optomechanically induced transparency 15,16 . Other than fundamental studies, a plethora of promising applications of cavity optomechanics, including tunable photonic filters and wavelength router 5,6 , wavelength conversion and switching 8,9 , radio-frequency optomechanical oscillators 17,18 and non-volatile optical memory 19 , have emerged.…”
mentioning
confidence: 99%
“…It has been long known that optomechanical coupling can mimic an effective Kerr-type nonlinearity [29], which can result in classical and quantum nonlinear phenomena such as optical bistability [30] and sub-Poissonian light [31]. Such strong and concentrated nonlinear effects, that can exceed even thermal nonlinearities in strength [32]- [33], paired with a low-noise platform, opens useful applications for light manipulation in nanophotonic devices [34].…”
mentioning
confidence: 99%
“…However, the radiation pressure coupling between the mechanical mode and optical mode has three consequences: photon shot noise, quantum backaction and dynamical backaction [1,9]. The dynamical backaction modifies the oscillator dynamics [10] and makes laser cooling [11,12] or amplification of phonons [13] in the mechanical system possible. Photon shot noise and quantum backaction, the former decreases with increasing input laser power while the latter increases with increasing input laser power, introduce two sources of noise on the displacement readout of the oscillator motion.…”
mentioning
confidence: 99%