Optomechanically-induced transparency in parity-time-symmetric microresonators

Jing, Hui; Özdemir, Şahin Kaya; Geng, Zhe; Zhang, Jing; Lü, Xin-You; Peng, Bo; Yang, Lan; Nori, Franco

doi:10.1038/srep09663

Cited by 296 publications

(222 citation statements)

References 47 publications

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“…Yan et al [150] investigated the amplification and transparency phenomena in a doublecavity optomechanical system. Jing et al [151] studied OMIT in a parity-time symmetric microcavity with a tunable gain-to-loss ratio. Schemes for ground-state cooling of mechanical resonators using the EIT interference have also been proposed [152][153][154][155][156][157].…”

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confidence: 99%

Electromagnetically induced transparency in optical microcavities

2017

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Electromagnetically induced transparency (EIT)is a quantum interference effect arising from different transition pathways of optical fields. Within the transparency window, both absorption and dispersion properties strongly change, which results in extensive applications such as slow light and optical storage. Due to the ultrahigh quality factors, massive production on a chip and convenient all-optical control, optical microcavities provide an ideal platform for realizing EIT. Here we review the principle and recent development of EIT in optical microcavities. We focus on the following three situations. First, for a coupled-cavity system, all-optical EIT appears when the optical modes in different cavities couple to each other. Second, in a single microcavity, all-optical EIT is created when interference happens between two optical modes. Moreover, the mechanical oscillation of the microcavity leads to optomechanically induced transparency. Then the applications of EIT effect in microcavity systems are discussed, including light delay and storage, sensing, and field enhancement. A summary is then given in the final part of the paper.

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confidence: 99%

Electromagnetically induced transparency in optical microcavities

2017

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“…(20) and (21). Here, we only consider the first sidebands (upper sideband with the frequency ω c + ω q and lower sideband with the frequency ω c − ω q ) by taking the linear approximation in the derivation of Eqs.…”

Section: Mechanical Pump Induced Sidebandsmentioning

confidence: 96%

Controllable optical output fields from an optomechanical system with mechanical driving

2015

Phys. Rev. A

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We investigate the properties of the optical output fields from a cavity optomechanical system, where the cavity is driven by a strong coupling and a weak probe optical fields and the mechanical resonator is driven by a coherent mechanical pump. When the frequency of the mechanical pump matches the frequency difference between the coupling and probe optical fields, due to the interference between the different optical components at the same frequency, we demonstrate that the large positive or negative group delay of the output field at the frequency of probe field can be achieved and tuned by adjusting the phase and amplitude of the mechanical driving field. Moreover, the strength of the output field at the frequency of optical four-wave-mixing (FWM) field also can be controlled (enhanced and suppressed) by tuning the phase and amplitude of the mechanical pump. We show that the power of the output field at the frequency of the optical FWM field can be suppressed to zero or enhanced so much that it can be comparable with and even larger than the power of the input probe optical field.

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“…Ta, 42.50.Wk Micromechanical resonators, in combination with a high Q optical cavity via resonantly enhanced feedback-backaction arising from radiation pressure, can be used to manipulate light propagation exotically [1,2] and provides a special platform for performing precision measurement [3][4][5] and force sensors [6,7] due to their important properties of small masses and high integrability. The force sensors based on the optomechanical interaction is usually carried out via the correlations between the measured quantities and output spectra, and precision measurement of electrical charges [8] in an optomechanical system has been suggested based on the effect of optomechanically induced transparency, where sharp transmission features controlled by the control laser beam exhibit Coulomb-interaction dependent effect that can be well understood through the linearization of the optomechanical interactions [9][10][11]. Compared with traditional methods, optomechanical sensors allows for remote sensing via optical fibers and relies free on naturally occurring resonances [3,4].…”

mentioning

confidence: 99%

“…The force sensors based on the optomechanical interaction is usually carried out via the correlations between the measured quantities and output spectra, and precision measurement of electrical charges [8] in an optomechanical system has been suggested based on the effect of optomechanically induced transparency, where sharp transmission features controlled by the control laser beam exhibit Coulomb-interaction dependent effect that can be well understood through the linearization of the optomechanical interactions [9][10][11]. Compared with traditional methods, optomechanical sensors allows for remote sensing via optical fibers and relies free on naturally occurring resonances [3,4].…”

mentioning

confidence: 99%

Highly sensitive optical sensor for precision measurement of electrical charges based on optomechanically induced difference-sideband generation

Xiong¹,

Liu²,

Wu³

2017

Opt. Lett.

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Difference-sideband generation in an optomechanical system coupled to a charged object is investigated beyond the conventional linearized description of optomechanical interactions. An exponential decay law for difference-sideband generation in the presence of electric interaction is identified which exhibits more sensitivity to electrical charges than the conventional linearized effects. Using exact the same parameters with previous work based on the linearized dynamics of the optomechanical interactions, we show that optomechanically induced difference-sideband generation may enable an all-optical sensor for precision measurement of electrical charges with higher precision and lower power. The proposed mechanism is especially suited for on-chip optomechanical devices, where nonlinear optomechanical interaction in the weak coupling regime is within current experimental reach.PACS numbers: 03.65. Ta, 42.50.Wk Micromechanical resonators, in combination with a high Q optical cavity via resonantly enhanced feedback-backaction arising from radiation pressure, can be used to manipulate light propagation exotically [1,2] and provides a special platform for performing precision measurement [3][4][5] and force sensors [6,7] due to their important properties of small masses and high integrability. The force sensors based on the optomechanical interaction is usually carried out via the correlations between the measured quantities and output spectra, and precision measurement of electrical charges [8] in an optomechanical system has been suggested based on the effect of optomechanically induced transparency, where sharp transmission features controlled by the control laser beam exhibit Coulomb-interaction dependent effect that can be well understood through the linearization of the optomechanical interactions [9][10][11]. Compared with traditional methods, optomechanical sensors allows for remote sensing via optical fibers and relies free on naturally occurring resonances [3,4].Recently, due to the prominent applications in precision measurement and optical combs, nonlinear optomechanical interactions have emerged as a new frontier in cavity optomechanics [12], and have enabled many interesting topics, such as second-order sideband generation [13][14][15][16], sideband comb [17,18], optomechanical chaos [19], and carrier-envelope phase-dependent effects [20]. It has been shown that nonlinear signals in the optomechanical system could be a sensitive tool for performing precision measurement of the average phonon number and may provide measurement with higher precision [21,22].Nonlinear features of optomechanical systems with multiple probe field driven have been discussed recently [23], and spectral signals at difference sideband has been demonstrated analytically which provides an effective way for light manipulation and precision measurement in a solid-state architecture [24]. In the present work, difference-sideband generation in an optomechanical system coupled to a charged object is analytically investigated and pre...

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Optomechanically-induced transparency in parity-time-symmetric microresonators

Cited by 296 publications

References 47 publications

Electromagnetically induced transparency in optical microcavities

Electromagnetically induced transparency in optical microcavities

Controllable optical output fields from an optomechanical system with mechanical driving

Highly sensitive optical sensor for precision measurement of electrical charges based on optomechanically induced difference-sideband generation

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