Chip-based soliton microcomb module using a hybrid semiconductor laser.

Photonic chip-based soliton microcombs have shown rapid progress and have already been used in many system-level applications. There has been substantial progress in realizing soliton microcombs that rely on compact laser sources, culminating in devices that only utilize a semiconductor gain chip or a self-injection-locked laser diode as the pump source. However, generating single solitons with electronically detectable repetition rates from a compact laser module has remained challenging. Here we demonstrate a current-initiated, Si3N4 chip-based, 99-GHz soliton microcomb driven directly by a compact, semiconductor-based laser. This approach does not require any complex soliton tuning techniques, and single solitons can be accessed by tuning the laser current. Further, we demonstrate a generic, simple, yet reliable, packaging technique to facilitate the fiber-chip interface, which allows building a compact soliton microcomb package that can benefit from the fiber systems operating at high power (> 100 mW). Both techniques can exert immediate impact on chip-based nonlinear photonic applications that require high input power, high output power, and interfacing chip-based devices to mature fiber systems.

[1]  Miles H. Anderson,et al.  A microphotonic astrocomb , 2017, Nature Photonics.

[2]  Scott A. Diddams,et al.  Searching for Exoplanets Using a Microresonator Astrocomb , 2018, Nature Photonics.

[3]  C. Koos,et al.  Ultrafast optical ranging using microresonator soliton frequency combs , 2017, Science.

[4]  Jonathan M. Silver,et al.  Sub-milliwatt-level microresonator solitons with extended access range using an auxiliary laser , 2018, Optica.

[5]  Michal Lipson,et al.  Breaking the Loss Limitation of On-chip High-confinement Resonators , 2016, 1609.08699.

[6]  H. Tang,et al.  High-fidelity cavity soliton generation in crystalline AlN micro-ring resonators. , 2018, Optics letters.

[7]  T. Kippenberg,et al.  Microresonator-Based Optical Frequency Combs , 2011, Science.

[8]  M. Gorodetsky,et al.  Frequency comb assisted diode laser spectroscopy for measurement of microcavity dispersion , 2009, 0907.0143.

[9]  S. Diddams,et al.  Thermal and Nonlinear Dissipative-Soliton Dynamics in Kerr-Microresonator Frequency Combs. , 2017, Physical review letters.

[10]  J. Bowers,et al.  High-power sub-kHz linewidth lasers fully integrated on silicon , 2019, Optica.

[11]  P. Morton,et al.  High-Power, Ultra-Low Noise Hybrid Lasers for Microwave Photonics and Optical Sensing , 2018, Journal of Lightwave Technology.

[12]  M. Gorodetsky,et al.  Temporal solitons in optical microresonators , 2012, Nature Photonics.

[13]  Tobias J. Kippenberg,et al.  Photonic Damascene Process for Low-Loss, High-Confinement Silicon Nitride Waveguides , 2018, IEEE Journal of Selected Topics in Quantum Electronics.

[14]  J. Bowers,et al.  Micro‐Resonator Soliton Generated Directly with a Diode Laser , 2017, 1711.06307.

[15]  Michal Lipson,et al.  Ultra-low-loss on-chip resonators with sub-milliwatt parametric oscillation threshold , 2017 .

[16]  Hairun Guo,et al.  Frequency-comb-assisted broadband precision spectroscopy with cascaded diode lasers. , 2016, Optics letters.

[17]  K. Vahala,et al.  Soliton microcomb range measurement , 2017, Science.

[18]  T. Kippenberg,et al.  Ultra-smooth silicon nitride waveguides based on the Damascene reflow process: fabrication and loss origins , 2018, Optica.

[19]  Hairun Guo,et al.  Double inverse nanotapers for efficient light coupling to integrated photonic devices. , 2018, Optics letters.

[20]  Jaime Cardenas,et al.  Fiber-to-chip fusion splicing for low-loss photonic packaging , 2019, Optica.

[21]  Huihui Lu,et al.  Photonic Packaging: Transforming Silicon Photonic Integrated Circuits into Photonic Devices , 2016 .

[22]  Miles H. Anderson,et al.  Microresonator-based solitons for massively parallel coherent optical communications , 2016, Nature.

[23]  H. Tang,et al.  Soliton microcomb generation at 2  μm in z-cut lithium niobate microring resonators. , 2019, Optics letters.

[24]  Michael L. Gorodetsky,et al.  Self-injection locking of a laser diode to a high-Q WGM microresonator , 2017 .

[25]  T. Hänsch,et al.  Optical frequency metrology , 2002, Nature.

[26]  Jeffrey A. Steidle,et al.  On-Chip Quantum Interference from a Single Silicon Ring-Resonator Source , 2015 .

[27]  E. Timurdogan,et al.  Low connector-to-connector loss through silicon photonic chips using ultra-low loss splicing of SMF-28 to high numerical aperture fibers. , 2019, Optics express.

[28]  Tobias J. Kippenberg,et al.  Coupling ideality of integrated planar high-Q microresonators , 2016, 1608.06607.

[29]  T. Kippenberg,et al.  Bringing short-lived dissipative Kerr soliton states in microresonators into a steady state. , 2016, Optics express.

[30]  Kerry J. Vahala,et al.  Microresonator soliton dual-comb spectroscopy , 2016, Science.

[31]  Marko Loncar,et al.  Monolithic lithium niobate photonic circuits for Kerr frequency comb generation and modulation , 2018, Nature Communications.

[32]  A. A. Savchenkov,et al.  High spectral purity Kerr frequency comb radio frequency photonic oscillator , 2015, Nature Communications.

[33]  M. Lipson,et al.  Battery-operated integrated frequency comb generator , 2018, Nature.

[34]  Vladimir S. Ilchenko,et al.  Rayleigh scattering in high-Q microspheres , 2000 .

[35]  M. Gorodetsky,et al.  Electrically pumped photonic integrated soliton microcomb , 2018, Nature Communications.