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1. Quantum photonics in triangular-cross-section nanodevices in silicon carbide

   https://doi.org/10.1088/2515-7647/abfdca  

   Majety, Sridhar; Norman, Victoria A; Li, Liang; Bell, Miranda; Saha, Pranta; Radulaski, Marina (June 2021, Journal of Physics: Photonics)

   Abstract Silicon carbide is evolving as a prominent solid-state platform for the realization of quantum information processing hardware. Angle-etched nanodevices are emerging as a solution to photonic integration in bulk substrates where color centers are best defined. We model triangular cross-section waveguides and photonic crystal cavities using Finite-Difference Time-Domain and Finite-Difference Eigensolver approaches. We analyze optimal color center positioning within the modes of these devices and provide estimates on achievable Purcell enhancement in nanocavities with applications in quantum communications. Using open quantum system modeling, we explore emitter-cavity interactions of multiple non-identical color centers coupled to both a single cavity and a photonic crystal molecule in SiC. We observe polariton and subradiant state formation in the cavity-protected regime of cavity quantum electrodynamics applicable in quantum simulation. 

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2. Design and fabrication of robust hybrid photonic crystal cavities

   https://doi.org/10.1515/nanoph-2024-0500  

   Abulnaga, Alex; Karg, Sean; Mukherjee, Sounak; Gupta, Adbhut; Baldwin, Kirk W; Pfeiffer, Loren N; de_Leon, Nathalie P (November 2024, Nanophotonics)

   Abstract Heterogeneously integrated hybrid photonic crystal cavities enable strong light–matter interactions with solid state, optically addressable quantum memories. A key challenge to realizing high quality factor (Q) hybrid photonic crystals is the reduced index contrast on the substrate compared to suspended devices in air. This challenge is particularly acute for color centers in diamond because of diamond’s high refractive index, which leads to increased scattering loss into the substrate. Here, we develop a design methodology for hybrid photonic crystals utilizing a detailed understanding of substrate-mediated loss, which incorporates sensitivity to fabrication errors as a critical parameter. Using this methodology, we design robust, high-Q, GaAs-on-diamond photonic crystal cavities, and by optimizing our fabrication procedure, we experimentally realize cavities withQapproaching 30,000 at a resonance wavelength of 955 nm. 

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3. A scalable cavity-based spin–photon interface in a photonic integrated circuit

   https://doi.org/10.1364/OPTICAQ.509233  

   Chen, Kevin_C; Christen, Ian; Raniwala, Hamza; Colangelo, Marco; De_Santis, Lorenzo; Shtyrkova, Katia; Starling, David; Murphy, Ryan; Li, Linsen; Berggren, Karl; et al (April 2024, Optica Quantum)

   A central challenge in quantum networking is transferring quantum states between different physical modalities, such as between flying photonic qubits and stationary quantum memories. One implementation entails using spin–photon interfaces that combine solid-state spin qubits, such as color centers in diamond, with photonic nanostructures. However, while high-fidelity spin–photon interactions have been demonstrated on isolated devices, building practical quantum repeaters requires scaling to large numbers of interfaces yet to be realized. Here, we demonstrate integration of nanophotonic cavities containing tin-vacancy (SnV) centers in a photonic integrated circuit (PIC). Out of a six-channel quantum microchiplet (QMC), we find four coupled SnV-cavity devices with an average Purcell factor of ∼7. Based on system analyses and numerical simulations, we find with near-term improvements this multiplexed architecture can enable high-fidelity quantum state transfer, paving the way toward building large-scale quantum repeaters. 

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4. Cavity-based Diamond Spin-Photon Interface in Photonic Integrated Circuits

   https://doi.org/10.1364/CLEO_AT.2023.JTu2A.49  

   Chen, Kevin C.; Christen, Ian; Raniwala, Hamza; Colangelo, Marco; Berggren, Karl; Englund, Dirk; Ben Dixon, P.; Zhang, Xingyu; Starling, David; Shtyrkova, Katia; et al (January 2023, Optica Publishing Group)

   We demonstrate heterogeneous integration of solid-state nanophotonic cavities into a scalable photonic platform as an efficient optical interface for quantum memories based on diamond color centers. 

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5. Integrated Quantum Nanophotonics with Solution‐Processed Materials

   https://doi.org/10.1002/qute.202100078  

   Chen, Yueyang; Sharp, David; Saxena, Abhi; Nguyen, Hao; Cossairt, Brandi_M; Majumdar, Arka (November 2021, Advanced Quantum Technologies)

   Abstract A key obstacle for all quantum information science and engineering platforms is their lack of scalability. The discovery of emergent quantum phenomena and their applications in active photonic quantum technologies have been dominated by work with single atoms, self‐assembled quantum dots, or single solid‐state defects. Unfortunately, scaling these systems to many quantum nodes remains a significant challenge. Solution‐processed quantum materials are uniquely positioned to address this challenge, but the quantum properties of these materials have remained generally inferior to those of solid‐state emitters or atoms. Additionally, systematic integration of solution‐processed materials with dielectric nanophotonic structures has been rare compared to other solid‐state systems. Recent progress in synthesis processes and nanophotonic engineering, however, has demonstrated promising results, including long coherence times of emitted single photons and deterministic integration of emitters with dielectric nano‐cavities. In this review article, these recent experiments using solution‐processed quantum materials and dielectric nanophotonic structures are discussed. The progress in non‐classical light state generation, exciton‐polaritonics for quantum simulation, and spin‐physics in these materials is discussed and an outlook for this emerging research field is provided. 

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