Linear Entropy and Entanglement in Two-Charge-Qubit Circuits

Qing-Hong Liao; Guang-Yu Fang; Yue-Yuan Wang; Muhammad Ahmad; Shu-Tian Liu

doi:10.1088/0256-307X/27/7/070304

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Linear Entropy and Entanglement in Two-Charge-Qubit Circuits

Journal article

Peer reviewed

Linear Entropy and Entanglement in Two-Charge-Qubit Circuits

Qing-Hong Liao, Guang-Yu Fang, Yue-Yuan Wang, Muhammad Ahmad and Shu-Tian Liu

Chinese physics letters, Vol.27(7), pp.070304-070304

01/07/2010

DOI: https://doi.org/10.1088/0256-307X/27/7/070304

Abstract

Charge

Circuits

Entropy

Evolution

Josephson junctions

Photons

Qubits (quantum computing)

Superconductivity

We consider a model that contains two coupled superconducting charge qubits by sharing a large Josephson junction. We examine the dynamical properties of the linear entropy of two qubits and the probability of both qubits being in an excited state. The results show that the initial mean photon number, the initial phase of the field and the relative phase of the two qubits' levels play an important role in the evolution of the linear entropy of the two qubits and the probability.

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Title: Linear Entropy and Entanglement in Two-Charge-Qubit Circuits
Creators - without role: Qing-Hong Liao
Guang-Yu Fang
Yue-Yuan Wang
Muhammad Ahmad
Shu-Tian Liu
Publication Details: Chinese physics letters, Vol.27(7), pp.070304-070304
Identifiers: 9938527308331
Academic Unit: King Abdulaziz University
Language: English
Resource Type: Journal article