Quasi-Phase-Matched Supercontinuum Generation in Photonic Waveguides

Hickstein, Daniel D.; Kerber, Grace C.; Carlson, David R.; Chang, Lin; Westly, Daron; Srinivasan, Kartik; Kowligy, Abijith S.; Bowers, John E.; Diddams, Scott A.

doi:10.1103/physrevlett.120.053903

Cited by 41 publications

(25 citation statements)

References 50 publications

(78 reference statements)

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“…Also, the tapering pattern can be used to produce single-photons with same frequencies but different polarisations, as commonly done in SPDC systems. Moreover, this technique can be applied in planar waveguides [25], this would help in advancing the rapidly-evolving integrated-quantum-photonics research field [38]. Finally, we anticipate that complex patterns can yield further desirable spectral properties, which inturn will produce exciting avenues of new research.…”

Section: Discussionmentioning

confidence: 95%

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Towards tailored single-photon sources using continuously-tapered waveguides

Greenwood¹,

Saleh²

2020

Frontiers in Optics / Laser Science

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In this paper, we present a thorough investigation for a spontaneous parametric four-wave mixing process in third-order nonlinear waveguides with various continuous tapering patterns. It has been previously shown that these devices can quasi-phase-match the four-wave-mixing process and enhance its conversion efficiency by orders of magnitude. By altering the tapering profile curve we found that these devices can enable single-photon sources with either narrow or broadband spectral widths at on-demand frequencies. Using our model, we were also able to identify the waveguide length at which the single-photon spectral purity is maximised.

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Section: Discussionmentioning

confidence: 95%

“…Periodically tapered waveguides (PTW) have also recently been proposed as a means to quasi-phase-match (QPM) parametric nonlinear processes in third-order nonlinear materials [25,26]. These structures are analogous to periodically-poled crystals [18].…”

Section: Introductionmentioning

confidence: 99%

Towards tailored single-photon sources using continuously-tapered waveguides

Greenwood¹,

Saleh²

2020

Frontiers in Optics / Laser Science

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“…Fundamentally, it constitutes a way to access ultra-broadband and coherent comb sources and is the key component in DFG for mid-IR frequency comb generation as well as the mid-IR DCS [15,16,30,31]. Recent advances have been on nanophotonic integrated waveguides, where lithographically tailorable supercontinuum generation is enabled at low pulse energies [32][33][34][35][36][37][38][39], in association with diverse photonic regimes such as QPM [40] and mode perturbation [41,42], and have been applied for laser self-referencing [43,44] and offset frequency detection [37,45] for DFG [46], as well as for spectroscopy [41,47]. In particular, Si 3 N 4 waveguides [48], combining a wide transparency with nanophotonic dispersion engineering, have been demonstrated to support mid-IR frequency comb generation based on dispersive wave generation from a femtosecond erbium fiber laser via supercontinuum generation [36,49].…”

Section: Nanophotonic Supercontinuum Generation With Supermode Dispermentioning

confidence: 99%

Nanophotonic supercontinuum-based mid-infrared dual-comb spectroscopy

Guo¹,

Weng²,

Liu³

et al. 2020

Optica

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High resolution and fast detection of molecular vibrational absorption is important for organic synthesis, pharmaceutical processes, and environmental monitoring, and is enabled by mid-infrared (mid-IR) laser frequency combs via dual-comb spectroscopy. Here, we demonstrate a novel and highly simplified approach to broadband mid-IR dual-comb spectroscopy via supercontinuum generation, achieved using unprecedented nanophotonic dispersion engineering that allows for ultra-broadband and flat-envelope mid-IR frequency combs. Our mid-IR dual-comb spectrometer has an instantaneous bandwidth covering the functional group region from 2800-3600 cm −1 , comprising more than 100,000 comb lines, enabling parallel gas-phase detection with a high sensitivity, sub-Doppler spectral resolution, and a high speed. In addition to the traditional functional groups, their isotopologues are also resolved in this supercontinuum-based dual-comb spectroscopy. Our approach combines well established fiber laser combs, digital coherent data averaging, and integrated nonlinear photonics, each in itself a state-of-the-art technology, signaling the emergence of mid-IR dual-comb spectroscopy for use outside of the protected laboratory environment.

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“…However, to realize these integrated microcomb-based systems, integrated photonic interposers that connect and operate on optical signals that transit between the many constituent photonic components will be critical. In fact, the pursuit of such integrated systems has driven recent progress in active photonics, e.g., lasers 29 – 32 and detectors 33 , nonlinear photonics in microresonators 5 – 9 , 34 , 35 and waveguides 36 – 39 , and passive photonics and heterogeneous integration 40 – 42 , and has motivated milestones such as the generation of microcombs using chip-scale lasers 43 – 45 . Photonic interposers that collect, filter, route, and interface light between many such active and passive devices are essential to realize the improvements in cost, size, weight, and power, performance, and scalability, offered by microcombs and integrated photonics, and will promote further system-level innovation using frequency combs.…”

Section: Introductionmentioning

confidence: 99%

Towards integrated photonic interposers for processing octave-spanning microresonator frequency combs

Rao

Moille

et al. 2021

Light Sci Appl

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Microcombs—optical frequency combs generated in microresonators—have advanced tremendously in the past decade, and are advantageous for applications in frequency metrology, navigation, spectroscopy, telecommunications, and microwave photonics. Crucially, microcombs promise fully integrated miniaturized optical systems with unprecedented reductions in cost, size, weight, and power. However, the use of bulk free-space and fiber-optic components to process microcombs has restricted form factors to the table-top. Taking microcomb-based optical frequency synthesis around 1550 nm as our target application, here, we address this challenge by proposing an integrated photonics interposer architecture to replace discrete components by collecting, routing, and interfacing octave-wide microcomb-based optical signals between photonic chiplets and heterogeneously integrated devices. Experimentally, we confirm the requisite performance of the individual passive elements of the proposed interposer—octave-wide dichroics, multimode interferometers, and tunable ring filters, and implement the octave-spanning spectral filtering of a microcomb, central to the interposer, using silicon nitride photonics. Moreover, we show that the thick silicon nitride needed for bright dissipative Kerr soliton generation can be integrated with the comparatively thin silicon nitride interposer layer through octave-bandwidth adiabatic evanescent coupling, indicating a path towards future system-level consolidation. Finally, we numerically confirm the feasibility of operating the proposed interposer synthesizer as a fully assembled system. Our interposer architecture addresses the immediate need for on-chip microcomb processing to successfully miniaturize microcomb systems and can be readily adapted to other metrology-grade applications based on optical atomic clocks and high-precision navigation and spectroscopy.

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Quasi-Phase-Matched Supercontinuum Generation in Photonic Waveguides

Cited by 41 publications

References 50 publications

Towards tailored single-photon sources using continuously-tapered waveguides

Towards tailored single-photon sources using continuously-tapered waveguides

Nanophotonic supercontinuum-based mid-infrared dual-comb spectroscopy

Towards integrated photonic interposers for processing octave-spanning microresonator frequency combs

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