High-Efficiency Measurement of an Artificial Atom Embedded in a Parametric Amplifier

Eddins, Andrew; Kreikebaum, John Mark; Toyli, D.M.; Levenson-Falk, E. M.; Dove, Allison; Livingston, William; Levitan, B. A.; Govia, Luke C. G.; Clerk, Aashish A.; Siddiqi, Irfan

doi:10.1103/physrevx.9.011004

Cited by 43 publications

(39 citation statements)

References 45 publications

(48 reference statements)

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“…In this case, the matrix Ω becomes an overall constant in the non-Hermtian Hamil-tonianĤ tb and can be ignored, and our mapping shows that the dynamics is equivalent to a simple two-mode NDPA in Eq. (38). We stress that this is a distinct mapping from that in Sec.…”

Section: A Standard Non-hermitian Pt -Symmetric Tight-binding Chainmentioning

confidence: 68%

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Non-Hermitian dynamics without dissipation in quantum systems

Wang

Clerk

2019

Phys. Rev. A

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Models based on non-Hermitian Hamiltonians can exhibit a range of surprising and potentially useful phenomena. Physical realizations typically involve couplings to sources of incoherent gain and loss; this is problematic in quantum settings, because of the unavoidable fluctuations associated with this dissipation. Here, we present several routes for obtaining unconditional non-Hermitian dynamics in non-dissipative quantum systems. We exploit the fact that quadratic bosonic Hamiltonians that do not conserve particle number give rise to non-Hermitian dynamical matrices. We discuss the nature of these mappings from non-Hermitian to Hermitian Hamiltonians, and explore applications to quantum sensing, entanglement dynamics and topological band theory. The systems we discuss could be realized in a variety of photonic and phononic platforms using the ubiquitous resource of parametric driving.

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Section: A Standard Non-hermitian Pt -Symmetric Tight-binding Chainmentioning

confidence: 68%

“…Note that the perturbation is now a standard dispersive coupling, something that arises in many measurement contexts. In the case where corresponds to the state of a qubit, this exact setup was realized in a recent superconducting quantum circuit experiment (though operated in a different regime) [38].…”

Section: A Exceptional Point Sensingmentioning

confidence: 99%

Non-Hermitian dynamics without dissipation in quantum systems

Wang

Clerk

2019

Phys. Rev. A

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“…Furthermore, in [43][44][45] it is shown that, in conjunction with continuous measurement, arbitrarily high levels of squeezing can be achieved in principle. This proposal is closely analogous to a recent experiment in circuit QED has used parametric drive of a microwave cavity to improve the effective efficiency of measurements on transmon qubits [46]. Importantly for quantum state tomography, parametric amplification adds no noise, in principle, and is therefore very effective at transducing small signals.…”

Section: Introductionmentioning

confidence: 80%

Tomography of an optomechanical oscillator via parametrically amplified position measurement

et al. 2019

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We propose a protocol for quantum state tomography of nonclassical states in optomechanical systems. Using a parametric drive, the procedure overcomes the challenges of weak optomechanical coupling, poor detection efficiency, and thermal noise to enable high efficiency homodyne measurement. Our analysis is based on the analytic description of the generalized measurement that is performed when optomechanical position measurement competes with thermal noise and a parametric drive. The proposed experimental procedure is numerically simulated in realistic parameter regimes, which allows us to show that tomographic reconstruction of otherwise unverifiable nonclassical states is made possible.

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“…The parameter choice is γ + =0.05γ − . 10 A straightforward way to verify this is to formulate the constraint equations in terms of the Bloch vectors (rather than the state vectors of equation (4)) then, due to the symmetry of the system, choose say v 1 =0. By inspection, this will lead to v 2 =v 3 =0 also.…”

Section: Wigner Invariance Of mentioning

confidence: 99%

“…Questions of this type [1] may offer novel insights into the nature of open quantum system dynamics and the quantum-classical epistemic distinction [2][3][4]. The observation of single quantum trajectories has now been realised in the laboratory [5][6][7][8][9], with ever increasing detection efficiencies [10]. Additionally, there is strong theoretical evidence for the stability of the particular class of quantum trajectories under consideration [11].…”

Section: Introductionmentioning

confidence: 99%

Symmetries and physically realisable ensembles for open quantum systems

Warszawski

Wiseman

2019

New J. Phys.

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A D-dimensional Markovian open quantum system will undergo stochastic evolution which preserves pure states, if one monitors without loss of information the bath to which it is coupled. If a finite ensemble of pure states satisfies a particular set of constraint equations then it is possible to perform the monitoring in such a way that the (discontinuous) trajectory of the conditioned system state is, at all long times, restricted to those pure states. Finding these physically realisable ensembles (PREs) is typically very difficult, even numerically, when the system dimension is larger than 2. In this paper, we develop symmetry-based techniques that potentially greatly reduce the difficulty of finding a subset of all possible PREs. The two dynamical symmetries considered are an invariant subspace and a Wigner symmetry. An analysis of previously known PREs using the developed techniques provides us with new insights and lays the foundation for future studies of higher dimensional systems.

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High-Efficiency Measurement of an Artificial Atom Embedded in a Parametric Amplifier

Cited by 43 publications

References 45 publications

Non-Hermitian dynamics without dissipation in quantum systems

Non-Hermitian dynamics without dissipation in quantum systems

Tomography of an optomechanical oscillator via parametrically amplified position measurement

Symmetries and physically realisable ensembles for open quantum systems

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