Resonant electro-optic frequency comb

Rueda, Alfredo; Sedlmeir, Florian; Kumari, Madhuri; Leuchs, Gerd; Schwefel, Harald G. L.

doi:10.1038/s41586-019-1110-x

Cited by 136 publications

(134 citation statements)

References 38 publications

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“…The monolithic lithium niobate on insulator (LNOI) platform has attracted significant interest for realization of next-generation nonlinear photonic devices and observation of new nonlinear dynamics due to its large c (2) (r33 = 3 ´ 10 -11 m/V) and c (3) nonlinearities (n2 = 1.8 ´ 10 -19 m 2 /W) [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16] . The LNOI platform is opening new opportunities for large-scale integration of optical and electronic devices on a single chip, as it combines the material properties of lithium niobate with the integration power of nano-photonics.…”

Section: Introductionmentioning

confidence: 99%

Raman lasing and soliton mode-locking in lithium niobate microresonators

et al. 2020

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The recent advancement in lithium niobate on insulator (LNOI) technology is revolutionizing the optoelectronic industry as devices of higher performance, lower power consumption, and smaller footprint can be realized due to the high optical confinement in the structures. The LNOI platform offers both large c (2) and c (3) nonlinearities along with the power of dispersion engineering, enabling brand new nonlinear photonic devices and applications towards the next generation of integrated photonic circuits. However, the Raman scattering, one of the most important nonlinear phenomena, have not been extensively studied, neither was its influences in dispersion-engineered LNOI nano-devices. In this work, we characterize the Raman radiation spectra in a monolithic lithium niobate (LN) microresonator via selective excitation of Raman-active phonon modes. Remarkably, the dominant mode for Raman oscillation is observed in the backward direction for a continuous-wave pump threshold power of 20 mW with a reportedly highest differential quantum efficiency of 46 %. In addition, we explore the effects of Raman scattering on Kerr optical frequency combs generation. We achieve, for the first time, soliton modelocking on a X-cut LNOI chip through sufficient suppression of the Raman effect via cavity geometry control. Our analysis of the Raman effect provides guidance for the development of future chip-based photonic devices on the LNOI platform.

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Section: Introductionmentioning

confidence: 99%

Raman lasing and soliton mode-locking in lithium niobate microresonators

et al. 2020

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“…The loaded microwave cavity had a quality of

Q \approx 200

at room temperature, limited by ohmic losses; the carefully polished LiNbO 3 , however, showed a particularly high optical Q of ≈10 8 . As well as up‐conversion, the system was also used to demonstrate efficient optical comb generation …”

Section: Experimental Approachesmentioning

confidence: 99%

“…As well as upconversion, the system was also used to demonstrate efficient optical comb generation. [82] In a double resonant system, the key parameter controlling conversion efficiency is the multiphoton cooperativity, [67,78]…”

Section: Electro-optic Couplingmentioning

confidence: 99%

Coherent Conversion Between Microwave and Optical Photons—An Overview of Physical Implementations

et al. 2019

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Quantum information technology based on solid state qubits has created much interest in converting quantum states from the microwave to the optical domain. Optical photons, unlike microwave photons, can be transmitted by fiber, making them suitable for long distance quantum communication. Moreover, the optical domain offers access to a large set of very well‐developed quantum optical tools, such as highly efficient single‐photon detectors and long‐lived quantum memories. For a high fidelity microwave to optical transducer, efficient conversion at single photon level and low added noise is needed. Currently, the most promising approaches to build such systems are based on second‐order nonlinear phenomena such as optomechanical and electro‐optic interactions. Alternative approaches, although not yet as efficient, include magneto‐optical coupling and schemes based on isolated quantum systems like atoms, ions, or quantum dots. Herein, the necessary theoretical foundations for the most important microwave‐to‐optical conversion experiments are provided, their implementations are described, and the current limitations and future prospects are discussed.

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“…To date, quantum coherent conversion schemes based on piezo-electromechanical [33,34], magneto-optical [35], and optomechanical [36][37][38][39][40] coupling have been developed. In addition, schemes based on cavity electro-optics [41] have been demonstrated using bulk [42][43][44] or integrated [45][46][47] Fig. 1d) and induce a phase shift on the input optical field E in (t), proportional to the voltage V (t) applied on the input microwave port of the device,…”

Section: K 3kmentioning

confidence: 99%

Cryogenic electro-optic interconnect for superconducting devices

Youssefi¹,

Shomroni²,

Joshi³

et al. 2020

Preprint

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Encoding information onto optical fields using electro-optical modulation is the backbone of modern telecommunication networks, offering vast bandwidth and low-loss transport via optical fibers. For these reasons, optical fibers are also replacing electrical cables for short range communications within data centers. Compared to electrical coaxial cables, optical fibers also introduce two orders of magnitude smaller heat load from room to milli-Kelvin temperatures, making optical interconnects based on electro-optical modulation an attractive candidate for interfacing superconducting quantum circuits and hybrid superconducting devices. Yet, little is known about optical modulation at cryogenic temperatures. Here we demonstrate a proof-of-principle cryogenic electro-optical interconnect, showing that currently employed Ti-doped lithium niobate phase modulators are compatible with operation down to 800mK ---below the typical operation temperature of conventional microwave amplifiers based on high electron mobility transistors (HEMTs)---and maintain their room temperature Pockels coefficient. We utilize cryogenic electro-optical modulation to perform spectroscopy of a superconducting circuit optomechanical system, measuring optomechanically induced transparency (OMIT). In addition, we encode thermomechanical sidebands from the microwave domain onto an optical signal processed at room temperature. Although the currently achieved noise figure is significantly higher than that of a typical HEMT, substantial noise reduction should be attainable by harnessing recent advances in integrated modulators, by increasing the modulator length, or by using materials with a higher electro-optic coefficient, leading to noise levels on par with HEMTs. Our work highlights the potential of electro-optical modulators for massively parallel readout for emerging quantum computing or cryogenic classical computing platforms.

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Resonant electro-optic frequency comb

Cited by 136 publications

References 38 publications

Raman lasing and soliton mode-locking in lithium niobate microresonators

Raman lasing and soliton mode-locking in lithium niobate microresonators

Coherent Conversion Between Microwave and Optical Photons—An Overview of Physical Implementations

Cryogenic electro-optic interconnect for superconducting devices

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