QuIC-TAQS: Implementation of a Neutral-Atom-Photonic-Cluster State

QuIC-TAQS：中性原子光子团簇态的实现

• 批准号: 2138068
• 负责人: Brian Smith
• 金额: $ 250万
• 依托单位: University of Oregon Eugene
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2021
• 资助国家: 美国
• 起止时间: 2021-08-01 至 2025-07-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2138068&HistoricalAwards=false
• 关键词: QuIC; TAQS; Implementation; Neutral; Atom

Quantum information science and technology (QIST) holds promise to transform radically our technological landscape by developing new computational, communications and sensing modalities as identified in the National Quantum Initiative. The potential long-term impacts on national needs of QIST are diverse and include enhancing scientific progress as well as economic and national security. Quantum Interconnects (QuICs), which enable transferring quantum information between different physical systems, are an essential class of components needed for the realization of QIST. The team will develop and demonstrate a novel interface between neutral atoms and photons, or light ‘particles’. Our approach is based on generating a correlated system of atoms and photons, known as a cluster state, that can be used for quantum computation, sensing and communications. By utilizing an integrated-optics (on-chip) platform to manipulate photons at telecommunications wavelengths, the PI and his collaborators aim to develop a system that can be readily deployed in quantum network applications. The impacts on basic science and engineering will be significant. For example, our work enables new ways to create and control large quantum systems, which could provide new approaches to simulate nature. This project contributes to a diverse quantum-ready workforce through training of graduate and undergraduate students and range of outreach activities.To produce neutral-atom-photonic cluster states this project combines the deterministic generation of primitive photonic cluster states via light single-atom emission with an integrated-optics platform. All-optical operations will be implemented on-chip to combine (‘fuse’) the primitive cluster states into larger ones that can serve for quantum information processing and enable overcoming loss in a quantum network. Specifically,the primitive photonic cluster states are generated by photon emission from single neutral rubidium atoms that are laser-trapped and strongly coupled to separate optical cavities defined in a common nanophotonic-crystal waveguide fabricated in silicon nitride. Laser and microwave controls cause the atom(s) to emit deterministically a sequence of single-photon wave packets that propagate along the waveguide axis. The photons carry information about the atomic state in their emission time. Photons can occupy a superposition of these ‘time bins’, corresponding to a time-bin quantum bit (‘qubit’). The photons are coupled into an external integrated-optics chip containing fast switches for combining the photon packets with appropriate delays designed for photonic ‘fusion gate’ operations, which are implemented by detecting a subset of photon outputs from the chip.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

量子信息科学与技术（QIST）有望通过开发国家量子计划中确定的新的计算，通信和传感模式，从根本上改变我们的技术格局。QIST对国家需求的潜在长期影响多种多样，包括促进科学进步以及经济和国家安全。量子互连（QuIC）能够在不同的物理系统之间传输量子信息，是实现QIST所需的基本组件。该团队将开发和展示中性原子和光子或光“粒子”之间的新界面。我们的方法是基于生成原子和光子的相关系统，称为簇态，可用于量子计算，传感和通信。通过利用集成光学（片上）平台来操纵电信波长的光子，PI和他的合作者旨在开发一种可以轻松部署在量子网络应用中的系统。对基础科学和工程的影响将是巨大的。例如，我们的工作使创建和控制大型量子系统的新方法成为可能，这可能为模拟自然提供新的方法。该项目通过培养研究生和本科生以及一系列推广活动，为多样化的量子准备工作人员做出贡献。为了产生中性原子光子团簇态，该项目将通过光单原子发射确定性生成原始光子团簇态与集成光学平台相结合。全光操作将在芯片上实现，以将原始簇态联合收割机（“融合”）组合成更大的簇态，这些簇态可以用于量子信息处理，并能够克服量子网络中的损耗。具体地说，原始光子簇态是由来自单个中性铷原子的光子发射产生的，所述中性铷原子被激光捕获并强烈耦合到在氮化硅中制造的普通纳米光子晶体波导中限定的单独光学腔。激光和微波控制使原子确定性地发射一系列单光子波包，这些波包沿着波导轴传播。光子在其发射时间内携带有关原子状态的信息。光子可以占据这些“时间仓”的叠加，对应于时间仓量子比特（“量子比特”）。光子被耦合到一个外部集成光学芯片，该芯片包含快速开关，用于将光子包与为光子“融合门”操作设计的适当延迟相结合，该操作通过检测来自芯片的光子输出子集来实现。该奖项反映了NSF的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。