Josephson charge qubits: a brief review

Pashkin, Yu. A.; Astafiev, O.; Yamamoto, Tsuyoshi; Nakamura, Y.; Tsai, Jaw Shen

doi:10.1007/s11128-009-0101-5

Cited by 69 publications

(60 citation statements)

References 71 publications

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“…Note that the thermal phonons of the NAMR have been ignored in Eq. (18), due to the assumption that the thermal phonons can be neglected since the high-frequency NAMR can be remained in its ground state at the work temperature (T = 20 mK) of the charge qubit [15,33]. We define the fidelity of the entangled cat state…”

Section: Simulation and Discussionmentioning

confidence: 99%

“…Using the realistic parameter values from Refs. [15,28,30,[33][34][35][36], we show in Figure 3 the numerical results for the fidelities of the generated state and the corresponding average phonon number T r(ρ(t)a † a) versus the decays of the charge qubit and the NAMR with respect to different Rabi frequencies, where we consider ±10% change of the Rabi frequency by parameter fluctuations.…”

Section: Simulation and Discussionmentioning

confidence: 99%

“…Moreover, the last condition ensures that the terms proportional to |g| 2 are negligible. Therefore, we obtain the following effective Hamiltonian Figure 2, the effective Hamiltonian (5) presents the main feature of the interaction Hamiltonian (4), particularly within the decoherence times of the transmon-type charge qubit and the NAMR (i.e., t < 50 µs [15,25,28,33]). …”

Section: Theoretical Model and The Effective Hamiltonianmentioning

confidence: 99%

“…By a single qubit operation, i.e., |e → (|g − |e )/ √ 2 and |g → (|g + |e )/ √ 2 [33], on the charge qubit, Eq. (16) changes as…”

Section: The Cat State With the State-dependent Displacement Opermentioning

confidence: 99%

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Generating the Schrödinger cat state in a nanomechanical resonator coupled to a charge qubit

et al. 2014

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We propose a scheme for generating the Schrödinger cat state based on geometric operations by a nanomechanical resonator coupled to a superconducting charge qubit. The charge qubit, driven by two strong classical fields, interacts with a high-frequency phonon mode of the nanomechanical resonator. During the operation, the charge qubit undergoes no real transitions, while the phonon mode of the nanomechanical resonator is displaced along different paths in the phase space, dependent on the states of the charge qubit. This generates the entangled cat state between the NAMR and charge qubit, and the cat state for the superposition of NAMR can be achieved after some operations applied on this entangled cat state. The robustness of the scheme is justified by considering noise from environment, and the feasibility of the scheme is discussed.

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Section: Simulation and Discussionmentioning

confidence: 99%

Section: Simulation and Discussionmentioning

confidence: 99%

Section: Theoretical Model and The Effective Hamiltonianmentioning

confidence: 99%

“…By a single qubit operation, i.e., |e → (|g − |e )/ √ 2 and |g → (|g + |e )/ √ 2 [33], on the charge qubit, Eq. (16) changes as…”

Section: The Cat State With the State-dependent Displacement Opermentioning

confidence: 99%

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Generating the Schrödinger cat state in a nanomechanical resonator coupled to a charge qubit

et al. 2014

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“…These experiments (as well as the experiment proposed in the present paper) touch upon the most intriguing property of quantum measurement: the presence of a "spooky" quantum back-action [4], which changes the system to agree with the observation, and cannot be explained in a realistic way, i.e. by using the Schrödinger equation.The quantum coherent (Rabi) oscillations in solid-state qubits are usually measured in an ensemble-averaged way [5,6] and decay within a short timescale, even though it can be much longer than the oscillation period. However, for a continuous weak measurement of a single qubit, the Rabi oscillations are non-decaying and can in principle be monitored in real time, as follows, e.g., from the quantum Bayesian formalism [7], which is generally similar to the formalism of quantum trajectories [8].…”

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confidence: 99%

Persistent Rabi oscillations probed via low-frequency noise correlation

Korotkov¹

2011

Phys. Rev. B

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The qubit Rabi oscillations are known to be non-decaying (though with a fluctuating phase) if the qubit is continuously monitored in the weak-coupling regime. In this paper we propose an experiment to demonstrate these persistent Rabi oscillations via low-frequency noise correlation. The idea is to measure a qubit by two detectors, biased stroboscopically at the Rabi frequency. The low-frequency noise depends on the relative phase between the two combs of biasing pulses, with a strong increase of telegraph noise in both detectors for the in-phase or anti-phase combs. This happens because of self-synchronization between the persistent Rabi oscillations and measurement pulses. Almost perfect correlation of the noise in the two detectors for the in-phase regime and almost perfect anticorrelation for the anti-phase regime indicates a presence of synchronized persistent Rabi oscillations. The experiment can be realized with semiconductor or superconductor qubits.The puzzle of the quantum state collapse due to measurement [1] is becoming accessible for the experimental study in solid state systems. Three experiments on non-projective collapse [2,3] have been recently realized with superconducting qubits. These experiments (as well as the experiment proposed in the present paper) touch upon the most intriguing property of quantum measurement: the presence of a "spooky" quantum back-action [4], which changes the system to agree with the observation, and cannot be explained in a realistic way, i.e. by using the Schrödinger equation.The quantum coherent (Rabi) oscillations in solid-state qubits are usually measured in an ensemble-averaged way [5,6] and decay within a short timescale, even though it can be much longer than the oscillation period. However, for a continuous weak measurement of a single qubit, the Rabi oscillations are non-decaying and can in principle be monitored in real time, as follows, e.g., from the quantum Bayesian formalism [7], which is generally similar to the formalism of quantum trajectories [8]. Persistence of the Rabi oscillations in this case is due to the quantum back-action, which tends to increase the amplitude of the oscillations to 100%, thus competing against decoherence. The persistent Rabi oscillations lead to the spectral peak of the detector signal at the Rabi frequency [9,10], which has been recently observed experimentally [3] (see also [11]). In the present paper we will discuss another way of demonstrating these oscillations.For definiteness let us discuss a "charge" qubit made of a double quantum dot (DQD) populated by a single electron, the location of which is continuously measured by a nearby quantum point contact (QPC). Analogous setups can be realized with spin-based or superconducting qubits. The continuous qubit evolution due to the quantum "informational" back-action can in principle be verified in a direct experiment [7]; however, it would require high-bandwidth recording of the detector signal (including shot noise) and fast qubit manipulation, that is still a big chall...

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Coherent Conversion Between Microwave and Optical Photons—An Overview of Physical Implementations

et al. 2019

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Quantum information technology based on solid state qubits has created much interest in converting quantum states from the microwave to the optical domain. Optical photons, unlike microwave photons, can be transmitted by fiber, making them suitable for long distance quantum communication. Moreover, the optical domain offers access to a large set of very well‐developed quantum optical tools, such as highly efficient single‐photon detectors and long‐lived quantum memories. For a high fidelity microwave to optical transducer, efficient conversion at single photon level and low added noise is needed. Currently, the most promising approaches to build such systems are based on second‐order nonlinear phenomena such as optomechanical and electro‐optic interactions. Alternative approaches, although not yet as efficient, include magneto‐optical coupling and schemes based on isolated quantum systems like atoms, ions, or quantum dots. Herein, the necessary theoretical foundations for the most important microwave‐to‐optical conversion experiments are provided, their implementations are described, and the current limitations and future prospects are discussed.

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Josephson charge qubits: a brief review

Cited by 69 publications

References 71 publications

Generating the Schrödinger cat state in a nanomechanical resonator coupled to a charge qubit

Generating the Schrödinger cat state in a nanomechanical resonator coupled to a charge qubit

Persistent Rabi oscillations probed via low-frequency noise correlation

Coherent Conversion Between Microwave and Optical Photons—An Overview of Physical Implementations

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