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1. Mesoscopic ultrafast nonlinear optics—the emergence of multimode quantum non-Gaussian physics

   https://doi.org/10.1364/OPTICA.514075  

   Yanagimoto, Ryotatsu; Ng, Edwin; Jankowski, Marc; Nehra, Rajveer; McKenna, Timothy_P; Onodera, Tatsuhiro; Wright, Logan_G; Hamerly, Ryan; Marandi, Alireza; Fejer, M_M; et al (June 2024, Optica)

   Over the last few decades, nonlinear optics has become significantly more nonlinear, traversing nearly a billionfold improvement in energy efficiency, with ultrafast nonlinear nanophotonics in particular emerging as a frontier for combining both spatial and temporal engineering. At present, cutting-edge experiments in nonlinear nanophotonics place us just above themesoscopicregime, where a few hundred photons suffice to trigger highly nonlinear dynamics. In contrast to classical or deep-quantum optics, the mesoscale is characterized by dynamical interactions between mean-field, Gaussian, and non-Gaussian quantum features, all within a close hierarchy of scales. When combined with the inherent multimode complexity of optical fields, such hybrid quantum-classical dynamics present theoretical, experimental, and engineering challenges to the contemporary framework of quantum optics. In this review, we highlight the unique physics that emerges in multimode nonlinear optics at the mesoscale and outline key principles for exploiting both classical and quantum features to engineer novel functionalities. We briefly survey the experimental landscape and draw attention to outstanding technical challenges in materials, dispersion engineering, and device design for accessing mesoscopic operation. Finally, we speculate on how these capabilities might usher in some new paradigms in quantum photonics, from quantum-augmented information processing to nonclassical-light-driven dynamics and phenomena to all-optical non-Gaussian measurement and sensing. The physics unlocked at the mesoscale present significant challenges and opportunities in theory and experiment alike, and this review is intended to serve as a guide to navigating this new frontier in ultrafast quantum nonlinear optics. 

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2. High Brightness Broadband Photon-Pairs at 2 μm in Lithium Niobate Nanophotonics

   https://doi.org/10.1364/CLEO_FS.2023.FF2L.2  

   Williams, James; Nehra, Rajveer; Sendonaris, Elina; Ledezma, Luis; Gray, Robert M; Sekine, Ryoto; Marandi, Alireza (January 2023, Optica Publishing Group)

   We present a photon-pair source at 2 µm with more than 45 THz bandwidth and a generation rate of 122 GHz/mW in lithium niobate nanophotonics, opening up many opportunities in mid-infrared quantum information processing. 

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3. Ultrafast control of vortex microlasers

   https://doi.org/10.1126/science.aba4597  

   Huang, Can; Zhang, Chen; Xiao, Shumin; Wang, Yuhan; Fan, Yubin; Liu, Yilin; Zhang, Nan; Qu, Geyang; Ji, Hongjun; Han, Jiecai; et al (February 2020, Science)

   The development of classical and quantum information–processing technology calls for on-chip integrated sources of structured light. Although integrated vortex microlasers have been previously demonstrated, they remain static and possess relatively high lasing thresholds, making them unsuitable for high-speed optical communication and computing. We introduce perovskite-based vortex microlasers and demonstrate their application to ultrafast all-optical switching at room temperature. By exploiting both mode symmetry and far-field properties, we reveal that the vortex beam lasing can be switched to linearly polarized beam lasing, or vice versa, with switching times of 1 to 1.5 picoseconds and energy consumption that is orders of magnitude lower than in previously demonstrated all-optical switching. Our results provide an approach that breaks the long-standing trade-off between low energy consumption and high-speed nanophotonics, introducing vortex microlasers that are switchable at terahertz frequencies. 

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4. Visible-to-mid-IR tunable frequency comb in nanophotonics

   https://doi.org/10.1038/s41467-023-42289-0  

   Roy, Arkadev; Ledezma, Luis; Costa, Luis; Gray, Robert; Sekine, Ryoto; Guo, Qiushi; Liu, Mingchen; Briggs, Ryan M.; Marandi, Alireza (October 2023, Nature Communications)

   Abstract Optical frequency comb is an enabling technology for a multitude of applications from metrology to ranging and communications. The tremendous progress in sources of optical frequency combs has mostly been centered around the near-infrared spectral region, while many applications demand sources in the visible and mid-infrared, which have so far been challenging to achieve, especially in nanophotonics. Here, we report widely tunable frequency comb generation using optical parametric oscillators in lithium niobate nanophotonics. We demonstrate sub-picosecond frequency combs tunable beyond an octave extending from 1.5 up to 3.3 μm with femtojoule-level thresholds on a single chip. We utilize the up-conversion of the infrared combs to generate visible frequency combs reaching 620 nm on the same chip. The ultra-broadband tunability and visible-to-mid-infrared spectral coverage of our source highlight a practical and universal path for the realization of efficient frequency comb sources in nanophotonics, overcoming their spectral sparsity. 

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5. Towards an engineering framework for ultrafast quantum nonlinear optics

   https://doi.org/10.1117/12.2576098  

   Yanagimoto, Ryotatsu; Ng, Edwin; Onodera, Tatsuhiro; Mabuchi, Hideo (March 2021, Ultrafast Phenomena and Nanophotonics XXV)

   Betz, Markus; Elezzabi, Abdulhakem Y. (Ed.)

   The advent of dispersion-engineered and highly nonlinear nanophotonics is expected to open up an all-optical path towards the strong-interaction regime of quantum optics by combining high transverse field confinement with ultra-short-pulse operation. Obtaining a full understanding of photon dynamics in such broadband devices, however, poses major challenges in the modeling and simulation of multimode non-Gaussian quantum physics, highlighting the need for sophisticated reduced models that facilitate efficient numerical study while providing useful physical insight. In this manuscript, we review our recent efforts in modeling broadband optical systems at varying levels of abstraction and generality, ranging from multimode extensions of quantum input-output theory for sync-pumped oscillators to the development of numerical methods based on a field-theoretic description of nonlinear waveguides. We expect our work not only to guide ongoing theoretical and experimental efforts towards next-generation quantum devices but also to uncover essential physics of broadband quantum photonics. 

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