Your search keyword '"Takabayashi AY"' showing total 9 results

1. Microresonator photonic wire bond integration for Kerr-microcomb generation.

Author

Takabayashi AY, Pavlov N, Rosborough V, Hoffman G, Kanger L, Koushyar FM, Huffman T, Nelson M, Turner C, Johansson L, Musolf J, Garrett H, Liu T, Morrison G, Chembo Y, Mattis B, Nguyen TA, Van Camp M, Turner SE, Karpov M, Jost J, and Burkley Z

Abstract

Extremely high-Q microresonators provide an attractive platform for a plethora of photonic applications including optical frequency combs, high-precision metrology, telecommunication, microwave generation, narrow linewidth lasers, and stable frequency references. Moreover, the desire for compactness and a low power threshold for nonlinear phenomena have spurred investigation into integrated and scalable solutions. Historically, crystalline microresonators with Q ∼ 10 9 were one of the first material platforms providing unprecedented optical performance in a small form factor. A key challenge, though, with these devices is in finding alternatives to fragile, bulky, and free-space couplers, such as tapered fibers, prisms, and cleaved fibers. Here, we present for the first time, the evanescent coupling of a photonic wire bond (PWB) to a MgF 2 -based microresonator to generate solitons and a pure, low-noise microwave signal based on Kerr-microcombs. These results open a path towards scalable integration of crystalline microresonators with integrated photonics. Moreover, because PWBs possess advantages over traditional coupling elements in terms of ease of fabrication, size, and flexibility, they constitute a more advanced optical interface for linear and nonlinear photonics., Competing Interests: Declarations. Competing interests: None of the authors have competing interests but we disclose in the interest of transparency that M.K. and J.J are co-founders of Enlightra. Additionally, T.N., Z.B., M.V.C, C.T., J.J, and L.J. have filed patent applications related, but not limited, to the subject matter disclosed in the manuscript., (© 2024. The Author(s).)

Published

2024

2. Correction: Integrated silicon photonic MEMS.

Author

Quack N, Takabayashi AY, Sattari H, Edinger P, Jo G, Bleiker SJ, Errando-Herranz C, Gylfason KB, Niklaus F, Khan U, Verheyen P, Mallik AK, Lee JS, Jezzini M, Zand I, Morrissey P, Antony C, O'Brien P, and Bogaerts W

Abstract

[This corrects the article DOI: 10.1038/s41378-023-00498-z.]., (© The Author(s) 2024.)

Published

2024

3. Correction: Integrated 4-terminal single-contact nanoelectromechanical relays implemented in a silicon-on-insulator foundry process.

Author

Li Y, Worsey E, Bleiker SJ, Edinger P, Kulsreshath MK, Tang Q, Takabayashi AY, Quack N, Verheyen P, Bogaerts W, Gylfason KB, Pamunuwa D, and Niklaus F

Abstract

Correction for 'Integrated 4-terminal single-contact nanoelectromechanical relays implemented in a silicon-on-insulator foundry process' by Yingying Li et al. , Nanoscale , 2023, https://doi.org/10.1039/d3nr03429a.

Published

2023

4. Fully reconfigurable MEMS-based second-order coupled-resonator optical waveguide (CROW) with ultra-low tuning energy.

Author

Lim MG, Park YJ, Choi DJ, Kim DU, Hong MS, Her MJ, Takabayashi AY, Jeong Y, Park J, Han S, Quack N, Bae Y, Yu K, and Han S

Abstract

Integrated microring resonators are well suited for wavelength-filtering applications in optical signal processing, and cascaded microring resonators allow flexible filter design in coupled-resonator optical waveguide (CROW) configurations. However, the implementation of high-order cascaded microring resonators with high extinction ratios (ERs) remains challenging owing to stringent fabrication requirements and the need for precise resonator tunability. We present a fully integrated on-chip second-order CROW filter using silicon photonic microelectromechanical systems (MEMS) to adjust tunable directional couplers and a phase shifter using nanoscale mechanical out-of-plane waveguide displacement. The filter can be fully reconfigured with regard to both the ER and center wavelength. We experimentally demonstrated an ER exceeding 25 dB and continuous wavelength tuning across the full free spectral range of 0.123 nm for single microring resonator, and showed reconfigurability in second-order CROW by tuning the ER and resonant wavelength. The tuning energy for an individual silicon photonic MEMS phase shifter or tunable coupler is less than 22 pJ with sub-microwatt static power consumption, which is far better than conventional integrated phase shifters based on other physical modulation mechanisms.

Published

2023

5. Integrated 4-terminal single-contact nanoelectromechanical relays implemented in a silicon-on-insulator foundry process.

Author

Li Y, Worsey E, Bleiker SJ, Edinger P, Kulsreshath MK, Tang Q, Takabayashi AY, Quack N, Verheyen P, Bogaerts W, Gylfason KB, Pamunuwa D, and Niklaus F

Abstract

Integrated nanoelectromechanical (NEM) relays can be used instead of transistors to implement ultra-low power logic circuits, due to their abrupt turn off characteristics and zero off-state leakage. Further, realizing circuits with 4-terminal (4-T) NEM relays enables significant reduction in circuit device count compared to conventional transistor circuits. For practical 4-T NEM circuits, however, the relays need to be miniaturized and integrated with high-density back-end-of-line (BEOL) interconnects, which is challenging and has not been realized to date. Here, we present electrostatically actuated silicon 4-T NEM relays that are integrated with multi-layer BEOL metal interconnects, implemented using a commercial silicon-on-insulator (SOI) foundry process. We demonstrate 4-T switching and the use of body-biasing to reduce pull-in voltage of a relay with a 300 nm airgap, from 15.8 V to 7.8 V, consistent with predictions of the finite-element model. Our 4-T NEM relay technology enables new possibilities for realizing NEM-based circuits for applications demanding harsh environment computation and zero standby power, in industries such as automotive, Internet-of-Things, and aerospace.

Published

2023

6. Integrated silicon photonic MEMS.

Author

Quack N, Takabayashi AY, Sattari H, Edinger P, Jo G, Bleiker SJ, Errando-Herranz C, Gylfason KB, Niklaus F, Khan U, Verheyen P, Mallik AK, Lee JS, Jezzini M, Morrissey P, Antony C, O'Brien P, and Bogaerts W

Abstract

Silicon photonics has emerged as a mature technology that is expected to play a key role in critical emerging applications, including very high data rate optical communications, distance sensing for autonomous vehicles, photonic-accelerated computing, and quantum information processing. The success of silicon photonics has been enabled by the unique combination of performance, high yield, and high-volume capacity that can only be achieved by standardizing manufacturing technology. Today, standardized silicon photonics technology platforms implemented by foundries provide access to optimized library components, including low-loss optical routing, fast modulation, continuous tuning, high-speed germanium photodiodes, and high-efficiency optical and electrical interfaces. However, silicon's relatively weak electro-optic effects result in modulators with a significant footprint and thermo-optic tuning devices that require high power consumption, which are substantial impediments for very large-scale integration in silicon photonics. Microelectromechanical systems (MEMS) technology can enhance silicon photonics with building blocks that are compact, low-loss, broadband, fast and require very low power consumption. Here, we introduce a silicon photonic MEMS platform consisting of high-performance nano-opto-electromechanical devices fully integrated alongside standard silicon photonics foundry components, with wafer-level sealing for long-term reliability, flip-chip bonding to redistribution interposers, and fibre-array attachment for high port count optical and electrical interfacing. Our experimental demonstration of fundamental silicon photonic MEMS circuit elements, including power couplers, phase shifters and wavelength-division multiplexing devices using standardized technology lifts previous impediments to enable scaling to very large photonic integrated circuits for applications in telecommunications, neuromorphic computing, sensing, programmable photonics, and quantum computing., Competing Interests: Conflict of interestThe authors declare no competing interests., (© The Author(s) 2023.)

Published

2023

7. Vacuum-sealed silicon photonic MEMS tunable ring resonator with an independent control over coupling and phase.

Author

Edinger P, Jo G, Van Nguyen CP, Takabayashi AY, Errando-Herranz C, Antony C, Talli G, Verheyen P, Khan U, Bleiker SJ, Bogaerts W, Quack N, Niklaus F, and Gylfason KB

Abstract

Ring resonators are a vital element for filters, optical delay lines, or sensors in silicon photonics. However, reconfigurable ring resonators with low-power consumption are not available in foundries today. We demonstrate an add-drop ring resonator with the independent tuning of round-trip phase and coupling using low-power microelectromechanical (MEMS) actuation. At a wavelength of 1540 nm and for a maximum voltage of 40 V, the phase shifters provide a resonance wavelength tuning of 0.15 nm, while the tunable couplers can tune the optical resonance extinction ratio at the through port from 0 to 30 dB. The optical resonance displays a passive quality factor of 29 000, which can be increased to almost 50 000 with actuation. The MEMS rings are individually vacuum-sealed on wafer scale, enabling reliable and long-term protection from the environment. We cycled the mechanical actuators for more than 4 × 10 9 cycles at 100 kHz, and did not observe degradation in their response curves. On mechanical resonance, we demonstrate a modulation increase of up to 15 dB, with a voltage bias of 4 V and a peak drive amplitude as low as 20 mV.

Published

2023

8. Silicon photonic microelectromechanical phase shifters for scalable programmable photonics.

Author

Edinger P, Takabayashi AY, Errando-Herranz C, Khan U, Sattari H, Verheyen P, Bogaerts W, Quack N, and Gylfason KB

Abstract

Programmable photonic integrated circuits are emerging as an attractive platform for applications such as quantum information processing and artificial neural networks. However, current programmable circuits are limited in scalability by the lack of low-power and low-loss phase shifters in commercial foundries. Here, we demonstrate a compact phase shifter with low-power photonic microelectromechanical system (MEMS) actuation on a silicon photonics foundry platform (IMEC's iSiPP50G). The device attains (2.9 π ± π ) phase shift at 1550 nm, with an insertion loss of (0.33-0.10+0.15) d B , a V π of (10.7-1.4+2.2) V , and an L π of (17.2-4.3+8.8)µ m . We also measured an actuation bandwidth f -3 d B of 1.03 MHz in air. We believe that our demonstration of a low-loss and low-power photonic MEMS phase shifter implemented in silicon photonics foundry compatible technology lifts a main roadblock toward the scale-up of programmable photonic integrated circuits.

Published

2021

9. Compact broadband suspended silicon photonic directional coupler.

Author

Sattari H, Takabayashi AY, Zhang Y, Verheyen P, Bogaerts W, and Quack N

Abstract

Directional couplers are extensively used in photonic integrated circuits as basic components for efficient on-chip photonic signal routing. Conventionally, directional couplers are fully encapsulated in the technology's waveguide cladding material. In this Letter, we demonstrate a compact broadband directional coupler, fully suspended in air and exhibiting efficient power coupling in the cross state. The coupler is designed and built based on IMEC's iSiPP50G standard platform, and hydrofluoric (HF) vapor-etching-based post-processing allows to release the freestanding component. A low insertion loss of 0.5 dB at λ =1560 n m and a 1 dB bandwidth of 35 nm at λ =1550 n m have been confirmed experimentally. With a small footprint of 20µ m ×30µ m and high mechanical stability, this directional coupler can serve as a basic building block for large-scale silicon photonic microelectromechanical systems (MEMS) circuits.

Published

2020