Energy-level attraction and heating-resistant cooling of mechanical resonators with exceptional points

Jiang, Cheng; Liu, Yu Long; Sillanpää, Mika

doi:10.1103/physreva.104.013502

Cited by 15 publications

(7 citation statements)

References 78 publications

(97 reference statements)

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“…This condition on σ can be fulfilled in our proposal by tuning the driving field instead of η, which is not easily tunable like the driving field. The parameters for our numerical simulations are from the realistic optomechanical setup implemented in [31], and the parameter η lies within the range 0  η  10 −5 which is in agreement with the experimental values derived above. Figure 2 shows the agreement between the numerical stability and the analytical investigation by the EP.…”

Section: Imsupporting

confidence: 84%

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Chaos control and exceptional point engineering via dissipative optomechanical coupling

Mbokop Tchounda,

Djorwé,

Tchakui

et al. 2024

Phys. Scr.

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We study a dissipative mechanically coupled optomechanical system that hosts gain and loss. The gain (loss) is engineered by driving a purely dispersive optomechanical cavity with a blue-detuned (red-detuned) electromagnetic field. By taking into account the dissipative coupling, the Exceptional Point (EP), which is a non-Hermitain degeneracy, occurs at low threshold driving strength compared to what happens in a solely dispersive system. In the linear regime, the dissipative term induces strong coupling between the mechanical resonators, leading to an increase of energy exchange. For strong enough driving, the system enters into a nonlinear regime where a weak coupling regime takes place. In this regime, the mechanical resonators exhibit chaotic beats like-behaviour in the purely dispersive system. By switching on the dissipative coupling, the complex dynamics is switched off, and this restores regular dynamics into the system. This work suggests a way to probe quantum phenomena in dissipative systems at low-threshold driving strength. It also provides a new control scheme of complex dynamics in optomechanics and related fields.

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Section: Imsupporting

confidence: 84%

“…Moreover, under the condition κ ? (G, γ j ), which is satisfied in our analysis, the cavity field can be eliminated adiabatically, and this leads us to the effective dynamical system for the two mechanical resonators [31]:…”

Section: Dynamical Equationsmentioning

confidence: 82%

Chaos control and exceptional point engineering via dissipative optomechanical coupling

Mbokop Tchounda,

Djorwé,

Tchakui

et al. 2024

Phys. Scr.

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“…Note added. Recently, we became aware of the work of Jiang et al based on a similar optomechanical setting reporting the ground-state cooling of mechanical resonators mediated by a phononic gauge field [93].…”

Section: Discussionmentioning

confidence: 99%

Static synthetic gauge field control of double optomechanically induced transparency in a closed-contour interaction scheme

Sütlüoğlu

Bulutay

2021

Phys. Rev. A

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We study theoretically an optical cavity and a parity-time (PT )-symmetric pair of mechanical resonators, where all oscillators are pairwise coupled, forming an optomechanical system with a closed-contour interaction. Due to the presence of both gain and feedback, we explore its stability and the root loci over a wide coupling range. Under the red-sideband pumping and for the so-called PT -unbroken phase, it displays a double optomechanically induced transparency (OMIT) for an experimentally realizable parameter set. We show that both the transmission amplitude and the group delay can be continuously steered from the lower transmission window to the upper one by the loop coupling phase which breaks the time-reversal symmetry and introduces a static synthetic gauge field. In the PT -unbroken phase both the gain-bandwidth and delay-bandwidth products remain constant over the full range of the controlling phase. Tunability in transmission and bandwidth still prevails in the PT -broken phase, albeit over a reduced range. In essence, we suggest a simple scheme that grants coupling phase-dependent control of the single and double OMIT phenomena within an effective PT -symmetric optomechanical system.

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“…Additionally, optomechanical devices in various configurations provide an excellent platform to study optically mediated interactions between mechanical resonators 12 – 14 . This lead to several phenomenon such as P and PT symmetry in mechanical resonators 15 – 17 , and dark mode control 9 . Optomechanical systems are a promising platform 18 – 23 to build sensors 19 , 24 and quantum information transducers 25 , 26 relying on the effect of electromagnetic radiation pressure on the vibrational modes of mechanical objects 27 , 28 ; for example, suspended micromirrors, membranes, microtoroids, microsphere resonators, micromembranes in superconducting circuits, 2D photonic crystals, photonic crystal nanobeams, and cold atoms in optical cavities 4 .…”

Section: Introductionmentioning

confidence: 99%

Optical coupling control of isolated mechanical resonators

Onah,

Jaramillo-Ávila,

Maldonado-Villamizar

et al. 2024

Sci Rep

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We present a Hamiltonian model describing two pairs of mechanical and optical modes under standard optomechanical interaction. The vibrational modes are mechanically isolated from each other and the optical modes couple evanescently. We recover the ranges for variables of interest, such as mechanical and optical resonant frequencies and naked coupling strengths, using a finite element model for a standard experimental realization. We show that the quantum model, under this parameter range and external optical driving, may be approximated into parametric interaction models for all involved modes. As an example, we study the effect of detuning in the optical resonant frequencies modes and optical driving resolved to mechanical sidebands and show an optical beam splitter with interaction strength dressed by the mechanical excitation number, a mechanical bidirectional coupler, and a two-mode mechanical squeezer where the optical state mediates the interaction strength between the mechanical modes.

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Energy-level attraction and heating-resistant cooling of mechanical resonators with exceptional points

Cited by 15 publications

References 78 publications

Chaos control and exceptional point engineering via dissipative optomechanical coupling

Chaos control and exceptional point engineering via dissipative optomechanical coupling

Static synthetic gauge field control of double optomechanically induced transparency in a closed-contour interaction scheme

Optical coupling control of isolated mechanical resonators

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