Scalable collective Lamb shift of a 1D superconducting qubit array in front of a mirror

Lin, K. Y.; Hsu, Ting; Lee, Chen-Yu; Hoi, I.-C.; Lin, Guin-Dar

doi:10.1038/s41598-019-55545-5

Cited by 9 publications

(5 citation statements)

References 57 publications

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“…This kind of dynamics is usually found in light mediated interaction in atomic systems [34][35][36] and superconducting qubits [32,33], for example. To illustrate our results, we consider four kind of geometries for a five-cell QB.…”

Section: A Exploring Network Effectsmentioning

confidence: 93%

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Quantum advantage of two-level batteries in self-discharging process

Santos

2020

Preprint

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Section: A Exploring Network Effectsmentioning

confidence: 93%

“…In particular, we assume this process in our study because it is the most common decoherence processes in a large of physical systems, e.g. in nuclear spin systems [27][28][29], cavity quantum electrodynamics [30] and superconducting qubits [31][32][33]. Then, by writing the density matrix in the QB basis |e and |g as…”

Section: Single-cell Qbsmentioning

confidence: 99%

Quantum advantage of two-level batteries in self-discharging process

Santos

2020

Preprint

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“…In the course of the last few decades, a significant number of theoretical approaches allowing one to tackle the waveguide QED problems within this limit was proposed. In particular, the Markovian waveguide QED systems are commonly examined theoretically with help of master equation based-approaches [1,[22][23][24][25][26][27]. Indeed, within the framework of the associated input-output formalism [1,28,29], Linblad-type equation approaches allow one to study transmission and reflection characteristics, as well as the photonic correlations for arbitrary initial photon states, including coherent, thermal, and Fock ones.…”

Section: Markovian Limit γτmentioning

confidence: 99%

Diagrammatic Approach to Scattering of Multi-Photon States in Waveguide QED

Piasotski,

Pletyukhov

2021

Preprint

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We give an exposure to diagrammatic techniques in waveguide QED systems. A particular emphasis is placed on the systems with delayed coherent quantum feedback. Specifically, we show that the N -photon scattering matrices in single-qubit waveguide QED systems, within the rotating wave approximation, admit for a parametrization in terms of N − 1-photon effective vertex functions and provide a detailed derivation of a closed hierarchy of generalized Bethe-Salpeter equations satisfied by these vertex functions. The advantage of this method is that the above mentioned integral equations hold independently of the number of radiation channels, their bandwidth, the dispersion of the modes they are supporting, and the structure of the radiation-qubit coupling interaction, thus enabling one to study multi-photon scattering problems beyond the Born-Markov approximation. Further, we generalize the diagrammatic techniques to the systems containing more than a single emitter by presenting an exact set of equations governing the generic two and three-photon scattering operators. The above described theoretical machinery is then showcased on the example of a three-photon scattering on a giant acoustic atom, recently studied experimentally [Nat. Phys. 15, 1123Phys. 15, (2019].

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“…Similar consideration applies to many-body cases, where both the real and virtual processes of photon exchange mediate the dipole-dipole interaction, resulting in cooperative decay and energy shift of the collective states. Recently, such phenomena have attracted extensive attention, and have been discussed in various contexts including atomic clouds [7,[11][12][13][14][15][16][17], one-dimensional atomic chains [18], ordered atomic arrays [19][20][21], nano-layer gases [22,23], ensembles of nuclei [24], trapped ions [25], and artificial atoms [26,27]. Another perspective views this shift as coupling between collective states, leading to Rabi-like excitation transfer among a few atoms [28].…”

Section: Introductionmentioning

confidence: 99%

Cooperative states and shift in resonant scattering of an atomic ensemble

Hsu,

Lin,

Lin

2024

New J. Phys.

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We investigate the spectral shift known as the collective Lamb shift in forward scattering for a cold dense atomic cloud. The shift results from resonant dipole-dipole interaction mediated by real and virtual photon exchange, forming many-body states displaying various super- and subradiant behaviour. However, the scattering spectrum reflects the overall contributions from these states but also averages out the radiative details associated with the underlying spin orders, causing ambiguity in determination and raising controversy on the scaling property of this shift. We employ a Monte-Carlo simulation to study how the collective states contribute to emission. We thus distinguish two kinds of collective shift that follow different scaling laws. One results from dominant occupation of the near-resonant collective states. This shift is usually small and insensitive to the density or the number of participating atoms. The other comes from large spatial correlation of dipoles, associated with the states of higher degree of emission. This corresponds to larger collective shift that is approximately linearly dependent on the optical depth. We further demonstrate that the spatial spin order plays an essential role in superradiant emission. Our analysis provides a novel perspective for understanding collective scattering and cooperative effects.

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Scalable collective Lamb shift of a 1D superconducting qubit array in front of a mirror

Cited by 9 publications

References 57 publications

Quantum advantage of two-level batteries in self-discharging process

Quantum advantage of two-level batteries in self-discharging process

Diagrammatic Approach to Scattering of Multi-Photon States in Waveguide QED

Cooperative states and shift in resonant scattering of an atomic ensemble

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