Generating synthetic magnetism via Floquet engineering auxiliary qubits in phonon-cavity-based lattice

Wang, Xin; Li, Hongrong; Li, Fuli

doi:10.1088/1367-2630/ab776e

Cited by 12 publications

(4 citation statements)

References 84 publications

(182 reference statements)

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“…The decoupling mechanism between the giant atom and modes in one propagating direction is similar to realize chiral quantum phenomena via generating synthetic gauge fields in discretized lattice model [18,[70][71][72][73]. Different from those studies, our proposal is based on giant atom effects in SQC platforms, and especially feasible for conventional continuous waveguides which are more robust to disorder noise than spin-chain channels.…”

Section: Momentum-dependent Coupling Between Giant Atoms and Pcwmentioning

confidence: 99%

Chiral quantum network with giant atoms

Wang

2022

Quantum Sci. Technol.

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In superconducting quantum circuits (SQCs), chiral routing quantum information is often realized with the ferrite circulators, which are usually buck, lossy and require strong magnetic ﬁelds. To overcome these problems, we propose a novel method to realize chiral quantum networks by exploiting the giant atom eﬀects in SQC platforms. By assuming each coupling point modulated with time, the interaction becomes momentum-dependent, and the giant atoms will chirally emit photons due to interference eﬀects. The chiral factor can approach 1, and both the emission direction and rate can be freely tuned by the modulating signals. We demonstrate that the high-ﬁdelity state transfer between remote giant atoms can be realized. Our proposal can be integrated on the superconducting chip easily, and has the potential to work as a tunable toolbox for quantum information processing in future chiral quantum networks.

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Section: Momentum-dependent Coupling Between Giant Atoms and Pcwmentioning

confidence: 99%

Chiral quantum network with giant atoms

Wang

2022

Quantum Sci. Technol.

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“…( 15) and ( 16) that the modulation phase θ is encoded into the DFI between atoms A and B, mimicking a synthetic magnetic flux for photons transferring in between. Although the coupling phase θ can be gauged away for such a two-atom model (thus it has no particular interest in this case), it can significantly affect the dynamics of the system when a third atom is introduced to form a closed-loop trimer [22,42,45,46], as will be shown below.…”

Section: Model and Equationsmentioning

confidence: 99%

Complex decoherence-free interactions between giant atoms

Du¹,

Guo²,

Li³

2022

Preprint

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Giant atoms provide a promising platform for engineering decoherence-free interactions which is a major task in modern quantum technologies. Here we study systematically how to implement complex decoherence-free interactions among giant atoms resorting to periodic coupling modulations and suitable arrangements of coupling points. We demonstrate that the phase of the modulation, which is tunable in experiments, can be encoded into the decoherence-free interactions, and thus enables the Aharonov-Bohm effect of photons when the giant atoms constitute an effective closed loop. In particular, we consider the influence of non-Markovian retardation effect arising from large separations of the coupling points and study its dependence on the modulation parameters.

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“…In this work, we discuss QED phenomena in a setup composed by quantum emitters and a Hofstadter-ladder waveguide. Different from previous studies based on lattice environment with synthetic gauge fields [56][57][58][59], here we mainly focus on unconventional QED phenomena induced by the spin-orbit coupling. First, we assume that the emitter is of small atom form which frequency is resonant with the lower energy band.…”

Section: Introductionmentioning

confidence: 99%

Unconventional Quantum Electrodynamics with Hofstadter-Ladder Waveguide

Wang,

Gao,

et al. 2022

Preprint

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We propose a novel quantum electrodynamics (QED) platform where quantum emitters interact with a Hofstadter-ladder waveguide. We demonstrate several intriguing phenomena stemming from the exotic dispersion relation and vacuum mode properties led by the effective spin-orbit coupling, which have no analog in other QED setups. First, by assuming emitter's frequency to be resonant with the lower band, we find that the spontaneous emission is chiral with most photonic field decaying unidirectionally. Both numerical and analytical results indicate that the Hofstadter-ladder waveguide can be engineered as a well-performed chiral quantum bus. Second, the dynamics of emitters of giant atom form is explored by considering their frequencies below the lower band. Due to quantum interference, we find that both the emitter-waveguide interaction and the amplitudes of bound states are periodically modulated by giant emitter's size. The periodical length depends on the positions of energy minima points induced by the spin-orbit coupling. Last, we consider the interaction between two giant emitters mediated by bound states, and find that their dipole-dipole interaction vanishes (is enhanced) when maximum destructive (constructive) interference happens.

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Generating synthetic magnetism via Floquet engineering auxiliary qubits in phonon-cavity-based lattice

Cited by 12 publications

References 84 publications

Chiral quantum network with giant atoms

Chiral quantum network with giant atoms

Complex decoherence-free interactions between giant atoms

Unconventional Quantum Electrodynamics with Hofstadter-Ladder Waveguide

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