Engineering of Zeno Dynamics in Integrated Photonics

Liu, Quancheng; Liu, Weijie; Ziegler, K.; Chen, Feng

doi:10.1103/physrevlett.130.103801

Cited by 10 publications

(7 citation statements)

References 48 publications

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“…S1 ). The weakly guided propagation (along z ) of optical waves in such a waveguide array follows the Schrödinger-type paraxial wave equation , where , ψ is the envelope of the light field of wavelength λ , corresponding to the wavenumber k = 2π/ λ , n 0 is the substrate refractive index, and Δ n ( x , y ; z ) is the index modulation 51 – 54 . This equation can be mapped to the conventional Schrödinger equation for z → t and −Δ n → V .…”

Section: Resultsmentioning

confidence: 99%

Floquet parity-time symmetry in integrated photonics

Liu,

et al. 2024

Nat Commun

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Parity-time (PT) symmetry has been unveiling new photonic regimes in non-Hermitian systems, with opportunities for lasing, sensing and enhanced light-matter interactions. The most exotic responses emerge at the exceptional point (EP) and in the broken PT-symmetry phase, yet in conventional PT-symmetric systems these regimes require large levels of gain and loss, posing remarkable challenges in practical settings. Floquet PT-symmetry, which may be realized by periodically flipping the effective gain/loss distribution in time, can relax these requirements and tailor the EP and PT-symmetry phases through the modulation period. Here, we explore Floquet PT-symmetry in an integrated photonic waveguide platform, in which the role of time is replaced by the propagation direction. We experimentally demonstrate spontaneous PT-symmetry breaking at small gain/loss levels and efficient control of amplification and suppression through the excitation ports. Our work introduces the advantages of Floquet PT-symmetry in a practical integrated photonic setting, enabling a powerful platform to observe PT-symmetric phenomena and leverage their extreme features, with applications in nanophotonics, coherent control of nanoscale light amplification and routing.

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Section: Resultsmentioning

confidence: 99%

Floquet parity-time symmetry in integrated photonics

Liu,

et al. 2024

Nat Commun

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“…In fact, the researches on DP are quite broad, including the dynamic evolution process of optical system [35,36] and physical system in time domain, such as synthetic dimension [37][38][39] and gauge field. [40] As for the photonic devices, DP is also widely studied in waveguide systems, [41][42][43] resonant cavity systems, [44][45][46] photonic crystal systems, [47][48][49] exciton systems. [50][51][52] Fig.…”

Section: Dynamic Photonicsmentioning

confidence: 99%

Progress and realization platforms of dynamic topological photonics

Yan 闫,

Ma 马,

Hu 胡

et al. 2023

Chinese Phys. B

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Dynamic topological photonics is a novel research field, combining the time-domain optics and topological physics. In this review article, the recent progress and realization platforms of dynamic topological photonics have been well introduced. The definition, measurement methods and the evolution process of the dynamic topological photonics are detailed demonstrated in order to better understand the physical diagram. This review is meant to bring the readers with a different perspective about topological photonics, grasp the advanced progress of dynamic topology, and inspire ideas about future prospects.

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“…[38][39][40] Early experimental realizations of QZE have been followed by exciting recent experiments having much more controls and precision. [41] Experimental realization of QZE paved the way for various applications of QZE, [38,[42][43][44][45] ranging from the enhancement of the resolution of absorp- tion tomography [44,45] to the demonstration of an entangling gate between two effectively non-interacting transmon qubits, [46] the reduction of communication complexity [47] to the QZE and QAZE based noise spectroscopy [48] to the utilization of QZE to achieve improved precision of metrology in the presence of non-Markovian noise. [49] Interesting applications of QZE and QAZE are also found in opposing decoherence by restricting the dynamics of the system in a decoherence-free subspace, [50] quantum interrogation measurement, [38] counterfactual secure quantum communication, [43,51] isolating quantum dot from its surrounding electron reservoir, [52] protecting the entanglement between two interacting atoms.…”

Section: Introductionmentioning

confidence: 99%

Quantum Zeno and Anti‐Zeno Effects in the Dynamics of Non‐Degenerate Hyper‐Raman Processes Coupled to Two Linear Waveguides

Das,

Sen,

Thapliyal

et al. 2023

Annalen der Physik

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The effect of the presence of two probe waveguides on the dynamics of hyper‐Raman processes is studied in terms of quantum Zeno and anti‐Zeno effects. Specifically, the enhancement (diminution) of the evolution of the hyper‐Raman processes due to interaction with the probe waveguides via evanescent waves is viewed as quantum Zeno (anti‐Zeno) effect. This study considers the two probe waveguides interacting with only one of the optical modes at a time. For instance, as a specific scenario, it is considered that the two non‐degenerate pump modes interact with each probe waveguide linearly, while Stokes and anti‐Stokes modes do not interact with the probes. Similarly, in another scenario, it is assumed both the probe waveguides interact with Stokes (anti‐Stokes) mode simultaneously. The present results show that quantum Zeno (anti‐Zeno) effect is associated with phase‐matching (mismatching). However, it do not find any relation between the presence of the quantum Zeno effect and antibunching in the bosonic modes present in the hyper‐Raman processes.

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Engineering of Zeno Dynamics in Integrated Photonics

Cited by 10 publications

References 48 publications

Floquet parity-time symmetry in integrated photonics

Floquet parity-time symmetry in integrated photonics

Progress and realization platforms of dynamic topological photonics

Quantum Zeno and Anti‐Zeno Effects in the Dynamics of Non‐Degenerate Hyper‐Raman Processes Coupled to Two Linear Waveguides

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