Novel architecture for ultra-stable micro-ring resonator based optical frequency combs (1405.1103v2)

Abstract: We report a novel geometry for OPOs based on nonlinear microcavity resonators. This approach relies on a self-locked scheme that enables OPO emission without the need for thermal locking of the pump laser to the microcavity resonance. By exploiting a CMOS-compatible microring resonator, we achieve oscillation with a complete absence of shutting down, or self-terminating behavior, a very common occurrence in externally pumped OPOs. Further, this scheme consistently produces very wide bandwidth (>300nm, limited by our experimental set-up) combs that oscillate at a spacing of the FSR of the micro cavity resonance.

• The paper demonstrates a novel self-locked architecture using a nested cavity design to achieve continuous, thermally resilient optical frequency comb generation.
• It employs a high-Q micro-ring within an amplifying fiber loop to produce combs exceeding 300 nm bandwidth with fixed free spectral range spacing.
• The paper shows that comb stability is maintained over nearly 30 nm pump wavelength variability, enhancing versatility for practical photonic applications.

Overview of a Novel Self-Locked Architecture for Micro-Ring Resonator-Based Optical Frequency Combs

The paper introduces a breakthrough in optical frequency comb (OFC) generation using a novel self-locked architecture in micro-ring resonators. This research addresses the common limitations associated with microresonator-based optical parametric oscillators (OPOs), such as thermal instability and self-termination, without requiring complex external feedback mechanisms.

The core innovation lies in the use of a self-locked approach that exploits a "nested cavity" configuration within an amplifying fiber loop, comprising a high-Q microring resonator. The paper demonstrates the generation of very wide bandwidth combs (>300 nm) with stable oscillation synchronized to the free spectral range (FSR) of the microcavity. Unlike conventional methods that necessitate external thermal locking, this approach intrinsically stabilizes the comb's operation against thermal and mechanical perturbations.

Key Findings

The paper highlights several significant contributions:

• Stable Comb Generation: The proposed structure achieves continuous, self-stabilized operation with persistent oscillation, demonstrating independence from thermal or mechanical fluctuations. The absence of self-termination over extended observation periods underscores this stability.
• Wide Bandwidth: The architecture consistently generates frequency combs exceeding a 300 nm bandwidth, maintaining a FSR spacing dictated by the microcavity. This feature is observed across a pump wavelength variability of nearly 30 nm within the gain bandwidth, presenting a significant improvement over conventional methods.
• Independent of Pump Wavelength: The generated OFCs are virtually independent of the precise central pump wavelength, a robust feature achieved without thermal locking constraints. This decoupling introduces versatility and flexibility in practical applications.

Experimental Setup

The experimental setup includes a microring resonator embedded within a fiber loop cavity containing an erbium-ytterbium doped fiber amplifier. Binoculars from the setup allowed control of the gain profile via an in-loop fiber bandpass filter, ensuring that only the modes within specific microring resonances are amplified. The microring exhibits negligible linear and nonlinear losses with a significant nonlinear parameter (γ~220 W/km), further contributing to efficient OFC generation. The described setup accomplishes consistent comb production with high repetition rates, evidenced by an optical spectrum analyzer.

Theoretical and Practical Implications

The novel self-locked architecture has notable implications in both theoretical and applied optics:

• Fundamental Understanding: The paper provides insights into the dynamics of self-locked systems, delineating distinctions and congruities with dissipative systems like the Filter-Driven Four Wave Mixing (FD-FWM) lasers. Insights gained here can be foundational for further exploration of soliton dynamics in microring resonators.
• Practical Applications: The robustness and operational independence of the proposed architecture present substantial potential for practical applications, including telecommunications and optical data processing. The ability to operate OFCs in a stable, thermally resilient manner using a CMOS-compatible platform can have ramifications for on-chip optical systems, optical clocks, and integrated photonics.

Future Directions

Future research can explore the optimization of this architecture for enhanced performance. Attaining higher output power through advanced filtering techniques (e.g., using fiber Bragg gratings) could extend the versatility of the system. Additionally, investigating the dynamics with varying microcavity parameters could yield further understanding of OFC generation in diverse operational regimes.

Overall, this paper presents a significant advancement in the field of optical frequency combs, offering a blueprint for creating stable, thermally resilient systems conducive to extensive application in optical technologies.