Generation of quantum entangled states of multiple groups of qubits distributed in multiple cavities

Liu, Tong; Su, Qi-Ping; Fang, Yu-Liang; Yang, Chui‐Ping

doi:10.1103/physreva.101.012337

Cited by 9 publications

(4 citation statements)

References 68 publications

(88 reference statements)

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“…In the past years, theoretical schemes for preparing multi-SC-qubit GHZ entangled states have been proposed [102][103][104][105][106][107], and the experimental production of GHZ entangled states with up to 18 SC qubits has been reported [12,18,19,[30][31][32][33][34]. The initial state of the whole system is thus given by…”

Section: B Generation Of Hybrid Ghz Entangled States With M Sc Qubits...mentioning

confidence: 99%

Single-step implementation of a hybrid controlled-not gate with one superconducting qubit simultaneously controlling multiple target cat-state qubits

Yang

2022

Phys. Rev. A

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Hybrid quantum gates have recently drawn considerable attention. They play significant roles in connecting quantum information processors with qubits of different encoding and have important applications in the transmission of quantum states between a quantum processor and a quantum memory. In this work, we propose a single-step implementation of a multi-target-qubit controlled-NOT gate with one superconducting (SC) qubit simultaneously controlling n target cat-state qubits. In this proposal, the gate is implemented with n microwave cavities coupled to a three-level SC qutrit. The two logic states of the control SC qubit are represented by the two lowest levels of the qutrit, while the two logic states of each target cat-state qubit are represented by two quasi-orthogonal cat states of a microwave cavity. This proposal operates essentially through the dispersive coupling of each cavity with the qutrit. The gate realization is quite simple because it requires only a single-step operation. There is no need of applying a classical pulse or performing a measurement. The gate operation time is independent of the number of target qubits, thus it does not increase as the number of target qubits increases. Moreover, because the third higher energy level of the qutrit is not occupied during the gate operation, decoherence from the qutrit is greatly suppressed. As an application of this hybrid multi-target-qubit gate, we further discuss the generation of a hybrid Greenberger-Horne-Zeilinger (GHZ) entangled state of SC qubits and cat-state qubits. As an example, we numerically analyze the experimental feasibility of generating a hybrid GHZ state of one SC qubit and three cat-state qubits within present circuit QED technology. This proposal is quite general and can be extended to implement a hybrid controlled-NOT gate with one matter qubit (of different type) simultaneously controlling multiple target cat-state qubits in a wide range of physical systems, such as multiple microwave or optical cavities coupled to a three-level natural or artificial atom.

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Section: B Generation Of Hybrid Ghz Entangled States With M Sc Qubits...mentioning

confidence: 99%

Single-step implementation of a hybrid controlled-not gate with one superconducting qubit simultaneously controlling multiple target cat-state qubits

Yang

2022

Phys. Rev. A

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“…Our physical interpretations of the HD-information and the Wehrl entropy-mixedness in qubit-cavity systems linked by a waveguide mode contribute to updating more potential applications for distributed quantum information processing that are based on realizing a multi-target-qubit unconventional geometric phase gate in a multi-cavity system [ 40 ], as well as entanglement stabilization protocols between two superconducting qubits that are coupled to distant cavities [ 41 ] and the architecture of the cavity-based quantum network [ 42 ]. It is found that certain coupling parameters of the exciton-cavity and the fiber-cavity interactions control the effects of the optical linear medium and the environment, which are major obstacles to the applications of the quantum information technology.…”

Section: Husimi Distribution (Hd)mentioning

confidence: 99%

“…This is of importance to the conception of quantum networks based on distributed quantum nodes (qubits) for the storage and manipulation of quantum data [ 32 , 38 , 39 ]. Recent applications for qubit-cavity systems are based on realizing a multi-target-qubit unconventional geometric phase gate [ 40 ], entanglement stabilization protocols [ 41 ], and the network architecture [ 42 ]. We are also interested to analyze the generation and robustness of the phase space information and the mixedness in the cavity-fiber systems depending on the Husimi distribution and Wehrl entropy quantifiers.…”

Section: Introductionmentioning

confidence: 99%

Nonclassical Effects Based on Husimi Distributions in Two Open Cavities Linked by an Optical Waveguide

Mohamed

Eleuch

2020

Entropy

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Nonclassical effects are investigated in a system formed by two quantum wells, each of which is inside an open cavity. The cavities are spatially separated, linked by a fiber, and filled with a linear optical medium. Based on Husimi distributions (HDs) and Wehrl entropy, we explore the effects of the physical parameters on the generation and the robustness of the mixedness and HD information in the phase space. The generated quantum coherence and the HD information depend crucially on the cavity-exciton and fiber cavity couplings as well as on the optical medium density. The HD information and purity are lost due to the dissipation. This loss may be inhibited by increasing the optical susceptibility as well as the couplings of the exciton-cavity and the fiber-cavity. These parameters control the regularity, amplitudes, and frequencies of the generated mixedness.

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“…This system allows quantum information to be encoded into two low-energy levels, with the transition being indirectly realized through a high-energy one. Some common three-level physical systems, such as nitrogen vacancy centers [24][25][26][27] and trapped ions [28][29][30], have been developed to reduce the unfavorable impact of decoherence on qubits.…”

Section: Introductionmentioning

confidence: 99%

High-fidelity quantum gates via optimizing short pulse sequences in three-level systems

Zhang,

Liu,

Song

et al. 2024

New J. Phys.

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We propose a robust and high-fidelity scheme for realizing universal quantum gates by optimizing short pulse sequences in a three-level system. To alleviate the sensitivity to the errors, we recombine all elements of error matrices to construct a cost function with three types of weight factors. The modulation parameters are obtained by searching for the minimum value of this cost function. The purposes of introducing the weight factors are to reduce the detrimental impact of high-order error matrices, suppress population leakage to the third state, correct the operational error in the qubit space, and optimize the total pulse area of short pulse sequences. The results demonstrate that the optimized sequences exhibit strong robustness against errors and effectively reduce the total pulse area. Therefore, this work presents a valuable method for achieving exceptional robustness and high speed in quantum computations.

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Generation of quantum entangled states of multiple groups of qubits distributed in multiple cavities

Cited by 9 publications

References 68 publications

Single-step implementation of a hybrid controlled-not gate with one superconducting qubit simultaneously controlling multiple target cat-state qubits

Single-step implementation of a hybrid controlled-not gate with one superconducting qubit simultaneously controlling multiple target cat-state qubits

Nonclassical Effects Based on Husimi Distributions in Two Open Cavities Linked by an Optical Waveguide

High-fidelity quantum gates via optimizing short pulse sequences in three-level systems

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