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Turnkey locking of quantum-dot lasers directly grown on Si

Bozhang Dong, Yating Wan, Weng W. Chow, Chen Shang, Artem Prokoshin, E. Alkhazraji, Rosalyn Koscica, Heming Wang, John E. Bowers

2024Nature Photonics37 citationsDOIOpen Access PDF

Abstract

Abstract Ultralow-noise laser sources are crucial for a variety of applications, including microwave synthesizers, optical gyroscopes and the manipulation of quantum systems. Silicon photonics has emerged as a promising solution for high-coherence applications due to its ability to reduce the system size, weight, power consumption and cost. Semiconductor lasers based on self-injection locking have achieved fibre laser coherence, but typically require a high-quality-factor external cavity to suppress coherence collapse through frequency-selective feedback. Lasers based on external-cavity locking are a low-cost and turnkey operation option, but their coherence is generally inferior to self-injection locking lasers. In this work, we demonstrate quantum-dot lasers grown directly on Si that achieve self-injection-locking laser coherence under turnkey external-cavity locking. The high-performance quantum-dot laser offers a scalable and low-cost heteroepitaxial integration platform. Moreover, the chaos-free nature of the quantum-dot laser enables a 16 Hz Lorentzian linewidth under external-cavity locking using a low-quality-factor external cavity, and improves the frequency noise by an additional order of magnitude compared with conventional quantum-well lasers.

Topics & Concepts

LaserLaser linewidthQuantum dot laserOptoelectronicsCoherence (philosophical gambling strategy)Materials scienceSemiconductor laser theoryQuantum dotOpticsInjection seederPhotonicsPhysicsQuantum mechanicsAdvanced Fiber Laser TechnologiesPhotonic and Optical DevicesOptical Network Technologies