Spatially-Encoded Photonic Quantum Information and Quantum Metrology

空间编码光子量子信息和量子计量

• 批准号: RGPIN-2020-05505
• 负责人: Lundeen, Jeffrey
• 金额: $ 4.06万
• 依托单位: University of Ottawa
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=762637
• 关键词: Spatially; Encoded; Photonic; Quantum; Information

Science is becoming adept at manipulating individual particles such as photons and electrons. The devices that we use these particles in have limits in sensitivity, speed, power, etc. that are set by the strange laws of quantum physics. The careful control of particles in these quantum technologies will allow us to build sensors with dramatically higher sensitivity (Quantum Metrology), computers than can solve intractable problems (Quantum Information), and the first provably secure communication systems (Quantum Cryptography). However, quantum physics is notoriously difficult to understand and contains many unresolved conceptual issues. This is both a problem and an opportunity. The areas of Quantum Information and Quantum Metrology both grew from avenues of enquiry into the area of Fundamental Issues in quantum physics, namely the study of quantum entanglement and measurement, respectively. Indeed, there has been a regular exchange of insights and tools between the three areas. This program will build upon my group's extensive experience in these three areas in order to translate concepts between them with the aim of revealing new applications and understandings. The field of Photonics brings many new possibilities to these three areas. Photonics applies modern technologies to light, such as the micro-fabrication used for computer chips, new types of lasers, and LCD displays. Whereas these applications are mainly based on the classical optics of the last century, this program will develop new kinds of photonic devices that function via the quantum physics of light, `quantum optics'. It will also use such quantum photonics to increase the sensitivity of light-based sensors, e.g. laser gyros, chemical and biological spectral sensors, and remote sensing optical devices. One of the reasons drug development is so incredibly expensive and failure prone is because humans are unable to predict how any given trialed drug-molecule behaves. Though still a distant possibility, a quantum computer would solve this problem by being able to model quantum mechanical systems such as molecules and solids and then predict their properties and behavior. This program is contributing to a global effort to build a quantum computer by leveraging photonic capabilities in order to develop novel ways to manipulate and utilize quantum light. Canada has been a pioneer and leader in both Photonic Telecommunications and Quantum Information. This research program capitalizes on the opportunity to join Canada's strength in these two areas to produce significant benefits for the country. Research at this intersection of engineering, computer science, mathematics, and physics will produce new technologies with diverse applications. The program aims to draw global talent to Canada and also to train highly skilled workers for Canadian Industry in in-demand industrial skills such as photonics design and for the coming revolution of quantum technologies.

科学正在变得擅长于操纵单个粒子，如光子和电子。我们使用这些粒子的设备在灵敏度、速度、功率等方面都有限制，这些限制是由量子物理的奇怪定律设置的。在这些量子技术中，对粒子的谨慎控制将使我们能够建造灵敏度大大提高的传感器(量子计量学)、能够解决棘手问题的计算机(量子信息)，以及第一个可证明是安全的通信系统(量子加密)。然而，众所周知，量子物理很难理解，而且包含许多尚未解决的概念问题。这既是一个问题，也是一个机会。量子信息和量子计量学的领域都是从研究量子物理基本问题的途径发展起来的，也就是分别研究量子纠缠和测量。事实上，这三个领域之间一直在定期交流见解和工具。这个项目将建立在我的团队在这三个领域的广泛经验的基础上，以便在它们之间转换概念，目的是揭示新的应用和理解。光子学领域为这三个领域带来了许多新的可能性。光子学将现代技术应用于光，例如用于计算机芯片、新型激光器和LCD显示器的微制造。尽管这些应用主要基于上个世纪的经典光学，但该计划将开发通过光的量子物理--量子光学--发挥作用的新型光子设备。它还将利用这种量子光子学来提高基于光的传感器的灵敏度，例如激光陀螺、化学和生物光谱传感器以及遥感光学设备。药物开发如此昂贵和容易失败的原因之一是因为人类无法预测任何给定的试验药物分子的行为。尽管可能性仍很遥远，但量子计算机将通过对分子和固体等量子力学系统进行建模，然后预测它们的性质和行为来解决这个问题。该计划正在为建立量子计算机的全球努力做出贡献，通过利用光子能力来开发操纵和利用量子光的新方法。加拿大一直是光子电信和量子信息领域的先驱和领导者。这项研究计划利用机会，将加拿大在这两个领域的力量结合起来，为国家带来重大利益。在工程学、计算机科学、数学和物理学的这个交叉点上的研究将产生具有不同应用的新技术。该计划旨在将全球人才吸引到加拿大，并为加拿大工业培训高技能工人，以掌握光子设计等急需的工业技能，以及即将到来的量子技术革命。