Linear analytical approach to dispersive, external dissipative, and intrinsic dissipative couplings in optomechanical systems

Baraillon, Joris; Taurel, Boris; Labeye, P.; Duraffourg, Laurent

doi:10.1103/physreva.102.033509

Cited by 16 publications

(8 citation statements)

References 31 publications

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“…A single mode (iii), located in the middle of the frequency range, and side modes ((i)-(ii);(iv)-(v) Figure 3d) are traits associated with the multilayer trace. These side modes are distinguished by a similarity of the quality factor (Table 2), which highlights the split resonance doublet trait and is attributed to a degeneracy excitement of the resonant modes caused by a dispersive coupling, in contraposition to dissipative coupling played by the resonant mode (iii) [9] [18] . By applying stress to the inner section of the two mirrors, a finite element analysis produces coherently, in-plane eigenmodes at the doublets and a dissipative out-of-plane deformation at 2.3 MHz (Figure 3e).…”

Section: B Plasmon-mechanical Couplingmentioning

confidence: 96%

“…Numerous sensing devices based on the coupling of the optical and mechanical domains [1][2][3][4] [5,6] in the form of optomechanical resonators (such as cantilevers [7] and cavities [8] ) have been developed during the past decade [1] as a result of recent micro and nanooptics advances. The optomechanical coupling is classified as dispersive and dissipative [9] , depending on whether the mechanical resonator modulates the resonant frequency by changing the cavity length or the decay rates by altering the optical input coupling or intracavity loss and these variations measure the system sensitivity. Interferometers in the form of Fabry-Pérot cavity are optomechanical resonators [10] [11] that are frequently used as extremely accurate force detectors [12,13] .…”

Section: Introductionmentioning

confidence: 99%

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Ag/Au alloy entangled in a protein matrix: A plasmonic substrate coupling surface plasmons and molecular chirality

Simone

Abdalla

2020

Applied Surface Science

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Section: B Plasmon-mechanical Couplingmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

Ag/Au alloy entangled in a protein matrix: A plasmonic substrate coupling surface plasmons and molecular chirality

Simone

Abdalla

2020

Applied Surface Science

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“…Furthermore, the amplitude of the output field is described by a relation involving the input field amplitude and the intracavity field amplitude, as established by the pertinent cavity input-output theory [18,[33][34][35][36], we obtain:…”

Section: Theoretical Description Of Optomechanical Couplingmentioning

confidence: 99%

Design and Analysis of Optomechanical Micro-Gyroscope for Angular-Vibration Detection

Hassan,

Huang,

Yan

et al. 2024

Photonics

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Micro-gyroscopes based on the Coriolis principle are widely employed in inertial navigation, motion control, and vibration analysis applications. Conventional micro-gyroscopes often exhibit limitations, including elevated noise levels and suboptimal performance metrics. Conversely, the advent of cavity optomechanical system technology heralds an innovative approach to micro-gyroscope development. This method enhances the device’s capabilities, offering elevated sensitivity, augmented precision, and superior resolution. This paper presents our main contributions which include a novel dual-frame optomechanical gyroscope, a unique photonic crystal cavity design, and advanced numerical simulation and optimization methods. The proposed design utilizes an optical cavity formed between dual oscillating frames, whereby input rotation induces a measurable phase shift via optomechanical coupling. Actuation of the frames is achieved electrostatically via an interdigitated comb-drive design. Through theoretical modeling based on cavity optomechanics and finite element simulation, the operating principle and performance parameters are evaluated in detail. The results indicate an expected angular rate sensitivity of 22.8 mV/°/s and an angle random walk of 7.1 × 10−5 °/h1/2, representing superior precision to existing micro-electromechanical systems gyroscopes of comparable scale. Detailed analysis of the optomechanical transduction mechanism suggests this dual-frame approach could enable angular vibration detection with resolution exceeding state-of-the-art solutions.

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“…Since the fluctuations of the quantum operators in these relationships are much smaller compared to their classical average values [13], we consider their changes in the form of a linear approximation, i.e., 𝑂 ̂= 𝑂 ̅ + 𝛿 ̂𝑂, where 𝑂 ̅ and 𝛿 ̂𝑂 are respectively the classical average value and fluctuation of the corresponding operator. On the other hand, according to the general model of optomechanical interactions, in which the internal and external dissipation rates of the cavity are dependent on the movement of the mechanical oscillator, we consider two regimes, Over- and external dissipation, internal dissipation coupling, external dissipation coupling and dispersive coupling rates respectively [14]. Also 𝑔 𝑜𝑚 = 𝜒 𝑐 ℏ ⁄ .…”

Section: Dynamic Equationsmentioning

confidence: 99%

An investigation of rotation rate sensitivity of a quantum optomechanical gyroscope with two coupled cavities

Saghafifar,

Mahdavi,

Davoudi-Darareh

2024

Preprint

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In this article, we have shown the design of a quantum optomechanical gyroscope, which is formed by combining a Michelson interferometer with a quantum optomechanical cavity coupled with a simple Fabry-Perot cavity, all located on a rotating table. The optomechanical cavity contains one movable mirror. The movement of the mirror is in both directions of the cavity axis(x-direction) and perpendicular to it(y-direction). A micro-piezoelectric carries out the movement of the mirror in the y-direction and is sinusoidal with the natural vibration frequency of the mirror in the x-direction. Despite the movement of the mirror in the y-direction and also the rotation of the gyroscope around the z-axis, the virtual Coriolis force enters the mirror in the x-direction. This affects the movement of the mirror, which was previously caused by thermal fluctuations and radiation pressure force. Also, the presence of a simple Fabry-Perot cavity and its coupling with the optomechanical cavity helps us to control the amount of energy entering the optomechanical cavity and consequently the radiation pressure inside it. Then in an optimal limit, we can get the best value of gyroscope sensitivity. In this article, we were able to achieve a sensitivity of 2.97 × 10−15 𝑟𝑎𝑑⁄𝑠 √𝐻𝑧 in angular velocity measurement by using this structure for the gyroscope. At the end of this article, by drawing Alan deviation diagrams in four temperatures 𝑇 = 0𝐾, 1𝑚𝐾, 10𝐾, 300𝐾, the values of the two basic parameters of gyroscopes, namely ARW and BS were obtained

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Linear analytical approach to dispersive, external dissipative, and intrinsic dissipative couplings in optomechanical systems

Cited by 16 publications

References 31 publications

Ag/Au alloy entangled in a protein matrix: A plasmonic substrate coupling surface plasmons and molecular chirality

Ag/Au alloy entangled in a protein matrix: A plasmonic substrate coupling surface plasmons and molecular chirality

Design and Analysis of Optomechanical Micro-Gyroscope for Angular-Vibration Detection

An investigation of rotation rate sensitivity of a quantum optomechanical gyroscope with two coupled cavities

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