Bandwidth Tunable Optical Bandpass Filter Based on Parity-Time Symmetry

Zhang, Bowen; Lü, Xin-You; Hu, Yu; Yang, Zihao; Zhang, Chi; Xu, Jing

doi:10.3390/mi13010089

Cited by 10 publications

(6 citation statements)

References 16 publications

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“…This filter enables the choice of a unique cavity-allowed mode (the central one in our case) among those comprising the cavity-modified joint spectrum [38] while preserving a high photon-pair emission rate per pump-power squared, ≈ 0.4 pairs/µW 2 . Integrated bandpass filters can be implemented from liquid crystals [42] or microresonator systems [43].…”

Section: The Heralded Single-photon Sourcementioning

confidence: 99%

An integrated photonic circuit for color qubit preparation by third-order nonlinear interactions

Aguayo-Alvarado

Domínguez-Serna

Cruz

et al. 2022

Sci Rep

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This work presents a feasible design of an integrated photonic circuit performing as a device for single-qubit preparation and rotations through the third-order nonlinear process of difference frequency generation (DFG) and defined in the temporal mode basis. The first stage of our circuit includes the generation of heralded single photons by spontaneous four-wave mixing in a micro-ring cavity engineered for delivering a single-photon state in a unique temporal mode. The second stage comprises the implementation of DFG in a spiral waveguide with controlled dispersion properties for reaching color qubit preparation fidelity close to unity. We present the generalized rotation operator related to the DFG process, a methodology for the device design, and qubit preparation fidelity results as a function of user-accessible parameters.

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Section: The Heralded Single-photon Sourcementioning

confidence: 99%

An integrated photonic circuit for color qubit preparation by third-order nonlinear interactions

Aguayo-Alvarado

Domínguez-Serna

Cruz

et al. 2022

Sci Rep

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“…One feasible way to address the problem is to adopt the frequencymodulation technology to match the targeted frequencies with good tuning controllability, which has been applied in tunable frequency optical combs, [26,27] single-photon diode, [28] and tunable bandpass filters. [29][30][31][32][33][34][35] Motivated by these considerations, we propose a novel frequency-tunable router of single photons based on a doublewaveguide structure connected by a whispering-gallery-mode resonator with a driven three-level system. To the best of our knowledge, few studies on frequency-tunable routing for single photons have been carried out.…”

Section: Introductionmentioning

confidence: 99%

Frequency-tunable single-photon router based on a microresonator containing a driven three-level emitter

Huang 黄,

Hu 胡,

Li 李

et al. 2024

Chinese Phys. B

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We propose a frequency tunable router of single photons with high routing efficiency, which is constructed by two waveguides mediately linked by a single-mode whispering gallery resonator with a driven three-level emitter. Quantum routing probability in the output port is obtained via the real-space Hamiltonian. By adjusting the resonator-emitter coupling and the drive, the desired continuous central frequencies for the resonance peaks of routing photons can be manipulated nearly linearly, with the assistance of Rabi splitting effect and optical Stark shift. The proposed routing system may provide potential applications in designing other frequency-modulation quantum optical devices, such as multiplexers, filters, and so.

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“…Periodic structures in optic and acoustic systems have emerged as an active field of scientific research in the last decades in different applications, such as sensors 1 – 5 , filters 6 , energy harvesting 7 , and smart windows 8 . Moreover, different equipment, buildings, and bridges are disturbed by different vibration sources and elastic waves in their surrounding environment.…”

Section: Introductionmentioning

confidence: 99%

Theoretical optimisation of a novel gas sensor using periodically closed resonators

Zaky,

Al-Dossari,

Sharma

et al. 2024

Sci Rep

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This study investigates using the phononic crystal with periodically closed resonators as a greenhouse gas sensor. The transfer matrix and green methods are used to investigate the dispersion relation theoretically and numerically. A linear acoustic design is proposed, and the waveguides are filled with gas samples. At the center of the structure, a defect resonator is used to excite an acoustic resonant peak inside the phononic bandgap. The localized acoustic peak is shifted to higher frequencies by increasing the acoustic speed and decreasing the density of gas samples. The sensitivity, transmittance of the resonant peak, bandwidth, and figure of merit are calculated at different geometrical conditions to select the optimum dimensions. The proposed closed resonator gas sensor records a sensitivity of 4.1 Hz m−1 s, a figure of merit of 332 m−1 s, a quality factor of 113,962, and a detection limit of 0.0003 m s−1. As a result of its high performance and simplicity, the proposed design can significantly contribute to gas sensors and bio-sensing applications.

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Bandwidth Tunable Optical Bandpass Filter Based on Parity-Time Symmetry

Cited by 10 publications

References 16 publications

An integrated photonic circuit for color qubit preparation by third-order nonlinear interactions

An integrated photonic circuit for color qubit preparation by third-order nonlinear interactions

Frequency-tunable single-photon router based on a microresonator containing a driven three-level emitter

Theoretical optimisation of a novel gas sensor using periodically closed resonators

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