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1. Performance analysis of quantum repeaters enabled by deterministically generated photonic graph states

   https://doi.org/10.22331/q-2023-02-16-924  

   Zhan, Yuan; Hilaire, Paul; Barnes, Edwin; Economou, Sophia E.; Sun, Shuo (February 2023, Quantum)

   By encoding logical qubits into specific types of photonic graph states, one can realize quantum repeaters that enable fast entanglement distribution rates approaching classical communication. However, the generation of these photonic graph states requires a formidable resource overhead using traditional approaches based on linear optics. Overcoming this challenge, a number of new schemes have been proposed that employ quantum emitters to deterministically generate photonic graph states. Although these schemes have the potential to significantly reduce the resource cost, a systematic comparison of the repeater performance among different encodings and different generation schemes is lacking. Here, we quantitatively analyze the performance of quantum repeaters based on two different graph states, i.e. the tree graph states and the repeater graph states. For both states, we compare the performance between two generation schemes, one based on a single quantum emitter coupled to ancillary matter qubits, and one based on a single quantum emitter coupled to a delayed feedback. We identify the numerically optimal scheme at different system parameters. Our analysis provides a clear guideline on the selection of the generation scheme for graph-state-based quantum repeaters, and lays out the parameter requirements for future experimental realizations of different schemes. 

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2. Inverse-designed photon extractors for optically addressable defect qubits

   https://doi.org/10.1364/OPTICA.408611  

   Chakravarthi, Srivatsa; Chao, Pengning; Pederson, Christian; Molesky, Sean; Ivanov, Andrew; Hestroffer, Karine; Hatami, Fariba; Rodriguez, Alejandro_W; Fu, Kai-Mei_C (December 2020, Optica)

   Solid-state defect qubit systems with spin-photon interfaces show great promise for quantum information and metrology applications. Photon collection efficiency, however, presents a major challenge for defect qubits in high refractive index host materials. Inverse-design optimization of photonic devices enables unprecedented flexibility in tailoring critical parameters of a spin-photon interface including spectral response, photon polarization, and collection mode. Further, the design process can incorporate additional constraints, such as fabrication tolerance and material processing limitations. Here, we design and demonstrate a compact hybrid gallium phosphide on diamond inverse-design planar dielectric structure coupled to single near-surface nitrogen-vacancy centers formed by implantation and annealing. We observe up to a 14-fold broadband enhancement in photon extraction efficiency, in close agreement with simulations. We expect that such inverse-designed devices will enable realization of scalable arrays of single-photon emitters, rapid characterization of new quantum emitters, efficient sensing, and heralded entanglement schemes. 

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3. Deterministic Generation of All-Photonic Quantum Repeaters from Solid-State Emitters

   https://doi.org/https://doi.org/10.1103/PhysRevX.7.041023  

   Buterakos, Donovan; Barnes, Edwin; Economou, Sophia E. (October 2017, Physical review. X)

   Quantum repeaters are nodes in a quantum communication network that allow reliable transmission of entanglement over large distances. It was recently shown that highly entangled photons in so-called graph states can be used for all-photonic quantum repeaters, which require substantially fewer resources compared to atomic-memory-based repeaters. However, standard approaches to building multiphoton entangled states through pairwise probabilistic entanglement generation severely limit the size of the state that can be created. Here, we present a protocol for the deterministic generation of large photonic repeater states using quantum emitters such as semiconductor quantum dots and defect centers in solids. We show that arbitrarily large repeater states can be generated using only one emitter coupled to a single qubit, potentially reducing the necessary number of photon sources by many orders of magnitude. Our protocol includes a built-in redundancy, which makes it resilient to photon loss. 

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4. A monolithic immersion metalens for imaging solid-state quantum emitters

   https://doi.org/10.1038/s41467-019-10238-5  

   Huang, Tzu-Yung; Grote, Richard R.; Mann, Sander A.; Hopper, David A.; Exarhos, Annemarie L.; Lopez, Gerald G.; Klein, Amelia R.; Garnett, Erik C.; Bassett, Lee C. (June 2019, Nature Communications)

   Abstract Quantum emitters such as the diamond nitrogen-vacancy (NV) center are the basis for a wide range of quantum technologies. However, refraction and reflections at material interfaces impede photon collection, and the emitters’ atomic scale necessitates the use of free space optical measurement setups that prevent packaging of quantum devices. To overcome these limitations, we design and fabricate a metasurface composed of nanoscale diamond pillars that acts as an immersion lens to collect and collimate the emission of an individual NV center. The metalens exhibits a numerical aperture greater than 1.0, enabling efficient fiber-coupling of quantum emitters. This flexible design will lead to the miniaturization of quantum devices in a wide range of host materials and the development of metasurfaces that shape single-photon emission for coupling to optical cavities or route photons based on their quantum state. 

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5. Generation of arbitrary all-photonic graph states from quantum emitters

   https://doi.org/10.1088/1367-2630/ab193d  

   Russo, Antonio; Barnes, Edwin; Economou, Sophia E. (May 2019, New Journal of Physics)

   Abstract We present protocols to generate arbitrary photonic graph states from quantum emitters that are in principle deterministic. We focus primarily on two-dimensional cluster states of arbitrary size due to their importance for measurement-based quantum computing. Our protocols for these and many other types of two-dimensional graph states require a linear array of emitters in which each emitter can be controllably pumped, rotated about certain axes, and entangled with its nearest neighbors. We show that an error on one emitter produces a localized region of errors in the resulting graph state, where the size of the region is determined by the coordination number of the graph. We describe how these protocols can be implemented for different types of emitters, including trapped ions, quantum dots, and nitrogen-vacancy centers in diamond. 

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