Dispersive Photon Blockade in a Superconducting Circuit

Hoffman, Anthony J.; Srinivasan, Srikanth; Schmidt, Sebastian; Spietz, Lafe; Aumentado, José; Türeci, Hakan E.; Houck, Andrew

doi:10.1103/physrevlett.107.053602

Cited by 307 publications

(278 citation statements)

References 32 publications

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“…An analogous phenomenon of phonon blockade was predicted for an artificial superconducting atom coupled to a nanomechanical resonator [23], as well as the polariton blockade effect due to polariton-polariton interactions has been considered in [24]. Recently, PB was considered in dispersive qubit-field interactions in a superconductive coplanar waveguide cavity [25] and with time-modulated input [26].…”

Section: Introductionmentioning

confidence: 99%

Multiphoton blockades in pulsed regimes beyond stationary limits

2014

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We demonstrate multiphoton blockades (PB) in the pulsed regime by using Kerr nonlinear dissipative resonator driven by a sequence of Gaussian pulses. It is shown that the results obtained for single-photon, two-photon and three-photon blockades in the pulsed excitation regime differ considerably from analogous results obtained for the case of continuous-wave (cw) driving. We strongly demonstrate that for the case of cw pumping of the Kerr-nonlinear resonator there are fundamental limits on populations of lower photonic number-states (with n = 0, 1, 2, 3). Thus, such detailed comparison demonstrates that PB due to excitation with a suitable photon pulses is realized beyond the fundamental limits established for cw excitations. We analyze photon-number effects and investigate phase-space properties of PB on the base of photon number populations, the second-order correlation functions and the Wigner functions in phase space. Generation of Fock states due to PB in the pulsed regime is analysed in details.

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Section: Introductionmentioning

confidence: 99%

Multiphoton blockades in pulsed regimes beyond stationary limits

2014

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“…The photon blockade results in a highly nonclassical emission of photons from the cavity, characterized by a strong antibunching. The photon blockade has been investigated theoretically and experimentally in a large variety of systems, such as atomic cavity QED [10,11], semiconductor nanostructures [12,13] and superconducting circuits [14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Fate of photon blockade in the deep strong-coupling regime

Boité¹,

Hwang²,

Nha³

et al. 2016

Phys. Rev. A

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We investigate the photon emission properties of the driven-dissipative Rabi model in the socalled ultrastrong and deep strong coupling regimes, where the atom-cavity coupling rate g becomes comparable or larger than the cavity frequency ωc. By solving numerically the master equation in the dressed-state basis, we compute the output field correlation functions in the steady-state for a wide range of coupling rates. We find that, as the atom-cavity coupling strength increases, the system undergoes multiple transitions in the photon statistics. In particular, a first sharp anti-bunching to bunching transition, occurring at g ∼ 0.45ωc, leading to the breakdown of the photon blockade due to the counter-rotating terms, is shown to be the consequence of a parity shift in the energy spectrum. A subsequent revival of the photon blockade and the emergence of the quasi-coherent statistics, for even larger coupling rates, are attributed to an interplay between the nonlinearity in the energy spectrum and the transition rates between the dressed states.

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“…In addition, one can introduce strong optical nonlinearity to the local cavities, by embedding qubits into it. In this case, the photons in the cavities can be thought as hard-core bosons due to photon blockade [15,23], i.e. b 2 j = b †2 j = 0, as long as the nonlinearity is much larger than the effective hopping strength between the resonators, g 2 b /∆ b .…”

Section: B Local Modelmentioning

confidence: 99%

“…Specifically, we consider a 2D on-chip circuit-QED quantum simulator consisting of hybrid resonator-qubit network, pioneered by a series of proposals, experiments [21][22][23][24][25][26][27]43]. As schematically shown in Fig.…”

Section: Quantum Optical Realizationmentioning

confidence: 99%

“…From an experimental standpoint, our protocol is motivated by the rapid development of quantum simulation and information technology in recent years, such as cavity quantum electrodynamics (QED) [15][16][17][18], circuit-QED [19][20][21][22][23][24][25][26][27][28], Rydberg atoms [29][30][31][32], and trapped ions [33]; it is within current technology to engineer an ancilla qubit coupled to a manybody system globally. The ancilla qubit can be either the cavity photon mode or the internal state of an atom.…”

Section: Introductionmentioning

confidence: 99%

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Measurement of many-body chaos using a quantum clock

2016

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There has been recent progress in understanding chaotic features in many-body quantum systems. Motivated by the scrambling of information in black holes, it has been suggested that the time dependence of out-of-timeordered (OTO) correlation functions such as O 2 (t)O 1 (0)O 2 (t)O 1 (0) is a faithful measure of quantum chaos. Experimentally, these correlators are challenging to access since they apparently require access to both forward and backward time evolution with the system Hamiltonian. Here, we propose a protocol to measure such OTO correlators using an ancilla which controls the direction of time. Specifically, by coupling the state of ancilla to the system Hamiltonian of interest, we can emulate the forward and backward time propagation, where the ancilla plays the role of a 'quantum clock'. Within this scheme, the continuous evolution of the entire system (the system of interest and the ancilla) is governed by a time-independent Hamiltonian. Our protocol is immune to errors that could occur when the direction of time evolution is externally controlled by a classical switch.

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Dispersive Photon Blockade in a Superconducting Circuit

Cited by 307 publications

References 32 publications

Multiphoton blockades in pulsed regimes beyond stationary limits

Multiphoton blockades in pulsed regimes beyond stationary limits

Fate of photon blockade in the deep strong-coupling regime

Measurement of many-body chaos using a quantum clock

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