Single-photon blockade in a hybrid optomechanical system involving two qubits in the presence of phononic number and coherent states

Rastegarzadeh, Mojtaba; Tavassoly, M. K.; Nadiki, M. Hassani

doi:10.1007/s11128-023-03840-6

Cited by 6 publications

(3 citation statements)

References 52 publications

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“…(2) j (0) (j = m, c) in Figure 3. [51][52][53] To provide further detail, in Figure 5a (in Figure 5b), valley points can be observed within the plots corresponding to probability amplitudes and the second-order correlation function in Figure 3a (in Figure 3b) for magnons (photons) located at the optimal detuning value Δ = Δ opt = 0.685𝜔 b (Δ = Δ opt = −0.66𝜔 b ).…”

Section: Resultsmentioning

confidence: 99%

“…Figure 5 clearly illustrates that the peaks and valleys in the plots for the probabilities of magnons (Figure 5a) and photons (Figure 5b) exactly coincide with the peaks and valleys in the plot of the second‐order correlation function

g_j^{(2)}(0)

(

j=m,c

) in Figure 3. [ 51–53 ] To provide further detail, in Figure 5a (in Figure 5b), valley points can be observed within the plots corresponding to probability amplitudes and the second‐order correlation function in Figure 3a (in Figure 3b) for magnons (photons) located at the optimal detuning value

\Delta = \Delta ^{\rm {opt}} = 0.685 \omega _b

(

\Delta = \Delta ^{\rm {opt}} = -0.66 \omega _b

).…”

Section: Resultsmentioning

confidence: 99%

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Achieving Strong Magnon Blockade through Magnon Squeezing in a Cavity Magnetomechanical System

Amazioug,

Dutykh,

Teklu

et al. 2023

Annalen der Physik

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A scheme that harnesses magnon squeezing under weak pump driving within a cavity magnomechanical system to achieve a robust magnon (photon) blockade is proposed. Through meticulous analytical calculations of optimal parametric gain and detuning values, the objective is to enhance the second‐order correlation function. The findings demonstrate a substantial magnon blockade effect under ideal conditions, accompanied by a simultaneous photon blockade effect. Impressively, both numerical and analytical results are found to be in complete accord, providing robust validation for the consistency of the findings. It is anticipated that the proposed scheme will serve as a pioneering approach toward the practical realization of magnon (photon) blockade in experimental cavity magnomechanical systems.

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Section: Resultsmentioning

confidence: 99%

g_j^{(2)}(0)

(

j=m,c

\Delta = \Delta ^{\rm {opt}} = 0.685 \omega _b

(

\Delta = \Delta ^{\rm {opt}} = -0.66 \omega _b

).…”

Section: Resultsmentioning

confidence: 99%

Achieving Strong Magnon Blockade through Magnon Squeezing in a Cavity Magnetomechanical System

Amazioug,

Dutykh,

Teklu

et al. 2023

Annalen der Physik

View full text Add to dashboard Cite

show abstract

“…This pivotal characteristic of optomechanical systems has spurred the exploration of macroscopic mechanical entanglement in a dual-cavity system. [29,[45][46][47] In line with this perspective, our paper is centered on the examination of quantum correlations and the generation of quantum entanglement between mechanical resonators within a double optomechanical cavity system.…”

Section: Introductionmentioning

confidence: 99%

Quantum correlations and entanglement in coupled optomechanical resonators with photon hopping via Gaussian interferometric power analysis

Lahlou,

Maroufi,

Daoud

2024

Chinese Phys. B

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Quantum correlations that surpass entanglement are of great importance in the realms of quantum information processing and quantum computation. Essentially, for quantum systems prepared in pure states, it is difficult to differentiate between quantum entanglement and quantum correlation. Nonetheless, this indistinguishability is no longer holds for mixed states. To contribute to a better understanding of this differentiation, we have explored a simple model for both generating and measuring these quantum correlations. Our study concerns two macroscopic mechanical resonators placed in separate Fabry-Perot cavities, coupled through the photon hopping process. this system offers a comprehensively way to investigate and quantify quantum correlations beyond entanglement between these mechanical modes. The key ingredient in analyzing quantum correlation in this system is the global covariance matrix. It forms the basis for computing two essential metrics: the Logarithmic Negativity ($E_\mathcal{N}^m$) and the Gaussian Interferometric Power ($\mathcal{P}_{\mathcal{G}}^{m}$). These metrics provide the tools to measure the degree of quantum entanglement and quantum correlations, respectively. Our study reveals, that the Gaussian Interferometric Power ($\mathcal{P}_{\mathcal{G}}^{m}$) proves to be a more suitable metric for characterizing quantum correlations among the mechanical modes in an optomechanical quantum system, particularly in scenarios featuring resilient photon hopping.

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Exploring Statistical and Nonclassical Properties in Cavity Optomechanical Systems Applying Arbitrary Single-mode Light States

Othman

2023

Int J Theor Phys

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Single-photon blockade in a hybrid optomechanical system involving two qubits in the presence of phononic number and coherent states

Cited by 6 publications

References 52 publications

Achieving Strong Magnon Blockade through Magnon Squeezing in a Cavity Magnetomechanical System

Achieving Strong Magnon Blockade through Magnon Squeezing in a Cavity Magnetomechanical System

Quantum correlations and entanglement in coupled optomechanical resonators with photon hopping via Gaussian interferometric power analysis

Exploring Statistical and Nonclassical Properties in Cavity Optomechanical Systems Applying Arbitrary Single-mode Light States

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