Canada-UK Quantum Technologies Call: Connectorizing Integrated Quantum Photonics Devices

加拿大-英国量子技术呼吁：连接集成量子光子器件

• 批准号: 556324-2020
• 负责人: Morandotti, Roberto
• 金额: $ 8.89万
• 依托单位: Institut national de la recherche scientifique
• 依托单位国家: 加拿大
• 项目类别: Alliance Grants
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=706275
• 关键词: Canada; UK; Quantum; Technologies; Call

Quantum networks can provide a revolutionary solution to our society's need for secure communication, as required, e.g., in the transmission of personal, bank, and government data. A quantum communication network consists of integrated local nodes allowing the generation of optical quantum states through single- and two-photon entangled sources, as well as their long-term storage through quantum memories. Photons are then shared among distant partners through a fiber-optic infrastructure connecting the local quantum nodes. Several approaches have been explored to realize integrated local nodes; quantum dots for single-photon sources, Chi(3) materials (e.g., Hydex glass) for two-photon sources, and spin-active impurities for quantum memories. However, two main bottlenecks prevent the development of quantum networks: (i) photon losses and (ii) the lack of a robust interconnection between the local nodes. The only way to achieve long-distance quantum communications is to minimize optical losses stemming from the network components. In this proposal, the PI aims, with the support of the industrial partner OEC, to develop low-loss and robust interconnects between integrated waveguide-based photonic chips and standard optical fibers, a crucial milestone towards the commercialization of fiber-based quantum secure communications. To this end, we will deliver (I) a microring resonator capable of generating high-dimensional frequency entangled photon pairs with novel enhanced coupling efficiency and performances, (II) low-loss photon processing schemes based on off-the-shelf fiber-based components, and (III) superconducting nanowire single-photon detectors with high-detection efficiency and optimized for coupling to different material platforms. This proposal features an extensive collaboration with UK academic and industrial teams, who will develop in parallel SiN-based photonics chips, as well as photon emitters and quantum memories. The targeted outcomes will benefit Canadian industry through the training of highly qualified personnel in the fields of integrated photonics and device design and will contribute to maintain Canada as a leading player in the quantum secure communication market.

量子网络可以根据需要为我们社会的安全通信需求提供革命性的解决方案，例如，个人银行和政府数据的传输量子通信网络由集成的本地节点组成，允许通过单光子和双光子纠缠源产生光量子态，以及通过量子存储器长期存储它们。然后，光子通过连接本地量子节点的光纤基础设施在遥远的合作伙伴之间共享。已经探索了几种方法来实现集成的局部节点;用于单光子源的量子点，Chi（3）材料（例如，氢化玻璃）用于双光子源，自旋活性杂质用于量子存储器。然而，两个主要瓶颈阻碍了量子网络的发展：（i）光子损失和（ii）本地节点之间缺乏鲁棒的互连。实现长距离量子通信的唯一方法是最大限度地减少网络组件的光损耗。在这项提案中，PI的目标是在工业合作伙伴OEC的支持下，在集成波导光子芯片和标准光纤之间开发低损耗和鲁棒的互连，这是基于光纤的量子安全通信商业化的重要里程碑。为此，我们将提供（I）能够产生具有新的增强耦合效率和性能的高维频率纠缠光子对的微谐振器，（II）基于现成的基于光纤的组件的低损耗光子处理方案，以及（III）具有高检测效率的超导纳米线单光子探测器，并优化耦合到不同的材料平台。该提案的特点是与英国学术和工业团队的广泛合作，他们将并行开发基于SiN的光子芯片，以及光子发射器和量子存储器。目标成果将通过培训集成光子学和设备设计领域的高素质人才使加拿大工业受益，并将有助于保持加拿大在量子安全通信市场的领先地位。