Chip-to-chip quantum photonic interconnect by path-polarization interconversion

Wang, J.; Bonneau, Damien; Villa, Matteo; Silverstone, Joshua W.; Santagati, Raffaele; Miki, Shigehito; Yamashita, Taro; Fujiwara, Mikio; Sasaki, Masahide; Terai, Hirotaka; Tanner, Michael G.; Natarajan, Chandra M.; Hadfield, Robert H.; O’Brien, Jeremy L; Thompson, Mark G.

doi:10.1364/optica.3.000407

Cited by 121 publications

(117 citation statements)

References 62 publications

(90 reference statements)

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“…Entangled path-encoded qubits can be generated by coherently pumping two spontaneous parametric down conversion (28,29) or spontaneous four-wave mixing (SFWM) photon-pair sources (30,31). The approach can be generalized to qudits via the generation of photons entangled over d spatial modes by coherently pumping d sources (28,32).…”

Section: Large-scale Integrated Quantum Photonic Circuitmentioning

confidence: 99%

Multidimensional quantum entanglement with large-scale integrated optics

Wang

Paesani

Ding

et al. 2018

Science

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694

599

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The ability to control multidimensional quantum systems is central to the development of advanced quantum technologies. We demonstrate a multidimensional integrated quantum photonic platform able to generate, control, and analyze high-dimensional entanglement. A programmable bipartite entangled system is realized with dimensions up to 15 × 15 on a large-scale silicon photonics quantum circuit. The device integrates more than 550 photonic components on a single chip, including 16 identical photon-pair sources. We verify the high precision, generality, and controllability of our multidimensional technology, and further exploit these abilities to demonstrate previously unexplored quantum applications, such as quantum randomness expansion and self-testing on multidimensional states. Our work provides an experimental platform for the development of multidimensional quantum technologies.

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Section: Large-scale Integrated Quantum Photonic Circuitmentioning

confidence: 99%

Multidimensional quantum entanglement with large-scale integrated optics

Wang

Paesani

Ding

et al. 2018

Science

Self Cite

694

599

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“…It is also demonstrated that the introduction of active (gain) media inside the plasmonic ENZ nanochannels can lead to perfect loss compensation of the inherent 28 (nonradiative) plasmonic losses that, subsequently, reduces decoherence and further boosts transient quantum entanglement. We envision that the presented passive and active ENZ mediated RET and entangled states will find applications in future quantum information and communications integrated systems on a chip [58,59], the design of new low-threshold subwavelength nanolasers [60], and the creation of ultrasensitive quantum metrology devices [61]. Hence, effective ENZ waveguide media have the potential to become crucial components to the emerging field of quantum plasmonics [9].…”

Section: Discussionmentioning

confidence: 99%

Resonance energy transfer and quantum entanglement mediated by epsilon-near-zero and other plasmonic waveguide systems

2019

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The entanglement and resonance energy transfer between two-level quantum emitters are typically limited to sub-wavelength distances due to the inherently short-range nature of the dipole-dipole interactions. Moreover, the entanglement of quantum systems is hard to preserve for a long time period due to decoherence and dephasing mainly caused by radiative and nonradiative losses. In this work, we outperform the aforementioned limitations by presenting efficient long-range inter-emitter entanglement and large enhancement of resonance energy transfer between two optical qubits mediated by epsilon-near-zero (ENZ) and other plasmonic waveguide types, such as V-shaped grooves and cylindrical nanorods. More importantly, we explicitly demonstrate that the ENZ waveguide resonant energy transfer and entanglement performance drastically outperforms the other waveguide systems. Only the excited ENZ mode has an infinite phase velocity combined with a strong and homogeneous electric field distribution, which leads to a giant energy transfer and efficient entanglement independent to the 2 emitters' separation distances and nanoscale positions in the ENZ nanowaveguide, an advantageous feature that can potentially accommodate multi-qubit entanglement. Moreover, the transient entanglement can be further improved and become almost independent of the detrimental decoherence effect when an optically active (gain) medium is embedded inside the ENZ waveguide. We also present that efficient steady-state entanglement can be achieved by using a coherent external pumping scheme. Finally, we report a practical way to detect the steady-state entanglement by computing the second-order correlation function. The presented findings stress the importance of plasmonic ENZ waveguides in the design of the envisioned onchip quantum communication and information processing plasmonic nanodevices. IntroductionOne of the main limitations of the current quantum photonic systems is the rapid loss of spatial and temporal coherence [1,2]. For instance, Förster resonance energy transfer [3], a well-known dipole-dipole interaction between quantum emitters important to light sources, biomedical imaging, and photovoltaic applications, is limited to subwavelength ranges [4,5]. In addition, quantum entanglement [6], which is significant for a variety of emerging applications in quantum communication and computing [7], usually takes place at extremely short distances and for very short time periods, due to the decoherence associated with unavoidable coupling between the system and the surrounding environment [8].During the last years, considerable research efforts have been dedicated to significantly improve coherence based on the emerging field of quantum plasmonic metamaterials [9,10]. These artificially engineered nanostructures can serve as a novel platform to trigger, harness, and enhance coherent light-matter interactions at the nanoscale [9,11]. For instance, long-range

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“…The photon pairs are finally sent to the part of quantum state analyzer to measure the property of path entanglement. The analyzer consists of two balanced MZIs, which can realize the  z R and  y R rotations on the signal/idler photons [23,29]. At the outputs of the MZIs, four grating couplers are used to couple the photons to optical fibers.…”

Section: ( )mentioning

confidence: 99%

Hybrid waveguide scheme for silicon-based quantum photonic circuits with quantum light sources

Yuan

et al. 2020

Photon. Res.

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We propose a hybrid silicon waveguide scheme to avoid the impact of noise photons induced by pump lights in application scenarios of quantum photonic circuits with quantum light sources. The scheme is composed of strip waveguide and shallow-ridge waveguide structures. It utilizes the difference of biphoton spectra generated by spontaneous four wave mixing (SFWM) in these two waveguides. By proper pumping setting and signal/idler wavelength selection, the generation of desired photon pairs is confined in the strip waveguide. The impact of noise photons generated by SFWM in the shallow-ridge waveguide could be avoided. Hence, the shallow-ridge waveguide could be used to realize various linear operation devices for pump light and quantum state manipulations. The feasibility of this scheme is verified by theoretical analysis and primary experiment. Two applications are proposed and analyzed, showing its great potential on silicon-based quantum photonic circuits. 1 W -1 at 1552.5 nm) than that of the shallow-ridge waveguide (93.5 m -1 W -1 at 1552.5 nm), since the strip waveguide has a much smaller effective mode field area.

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Chip-to-chip quantum photonic interconnect by path-polarization interconversion

Cited by 121 publications

References 62 publications

Multidimensional quantum entanglement with large-scale integrated optics

Multidimensional quantum entanglement with large-scale integrated optics

Resonance energy transfer and quantum entanglement mediated by epsilon-near-zero and other plasmonic waveguide systems

Hybrid waveguide scheme for silicon-based quantum photonic circuits with quantum light sources

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