Collaborative Research: RUI: Weak and Protective Measurements in the Time Domain

合作研究：RUI：时域中的弱测量和保护性测量

• 批准号: 2109964
• 负责人: Lucas Illing
• 金额: $ 19.82万
• 依托单位: Reed College
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2021
• 资助国家: 美国
• 起止时间: 2021-09-01 至 2024-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2109964&HistoricalAwards=false
• 关键词: Collaborative; Research; RUI; Weak; Protective

This project will realize new ways of measuring a quantum system. In physics, the concept of a measurement is extremely important. We can only learn about the world around us by performing measurements, e.g., when you look at something you are “measuring" it with your eye. In classical physics, measurements can be performed without disturbance—one gains information about an object without changing its state. (The trajectory of a baseball is unchanged as you look at it). In quantum mechanics, however, it was long believed that a measurement would nearly always change the state of the system, the wave function would “collapse," and there was no way around that fact. Recently that belief has been challenged, as physicists have come to realize that it is possible to perform so-called weak or protective measurements in which one gains information about the object while only minimally disturbing its state. Such types of measurements have been transforming the landscape of quantum measurements. They also offer technologically important applications in quantum information processing. In this project, the group will implement new experimental techniques for performing weak and protective measurements. These techniques promise to provide significant improvements in measurement performance and flexibility over existing experiments. In parallel, the group will advance our understanding of weak and protective measurements through theoretical investigations, whose predictions will in turn be tested by the experiments. Much of the work will be performed by a diverse group of undergraduate students, providing an excellent opportunity for them to develop research skills and further their scientific careers.This project will experimentally realize weak and protective measurements with single photons and complement these experiments with theoretical studies. The experimental approach is characterized by using the temporal differential group delay (DGD) between polarization components as a measuring “pointer." The group will construct a source of narrow-band, pure-state, single photons in the telecommunications C-band (~1550 nm) and use it to first implement a weak measurement of polarization by directly measuring photon arrival times after the DGD. This basic setup will then serve as the central building block of a novel experimental realization of a protective measurement in the time domain by utilizing DGD in a loop configuration to measure expectation values of photon polarization. The optical loop will enable the team to pass the photons repeatedly through the same measurement and state-protection stage, thus implementing the protective measurement. In the theoretical portion of the project, the group will study several important properties of protective measurements and their performance, including: the effect of diminished state purity on the measurement, photon survival probabilities, and the uncertainty in the final measurement. These theoretical activities will generate models and predictions that can be tested by experiment and that will enhance our understanding of protective measurements.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.

该项目将实现测量量子系统的新方法。在物理学中，测量的概念非常重要。我们只能通过测量来了解我们周围的世界，例如，当你看东西的时候，你是在用眼睛“测量”它。在经典物理学中，测量可以在不受干扰的情况下进行，即在不改变物体状态的情况下获得物体的信息。(The棒球的轨迹在你看它的时候是不变的）。然而，在量子力学中，人们一直认为测量几乎总是会改变系统的状态，波函数会“坍缩”，而且没有办法绕过这个事实。最近，这种信念受到了挑战，因为物理学家已经意识到，可以进行所谓的弱测量或保护测量，其中人们可以获得有关物体的信息，而只需最小限度地干扰其状态。这种类型的测量已经改变了量子测量的前景。它们还在量子信息处理方面提供了重要的技术应用。在这个项目中，该小组将实施新的实验技术，用于执行弱和保护性测量。这些技术承诺提供显着的改善，在测量性能和灵活性，超过现有的实验。与此同时，该小组将通过理论研究推进我们对弱测量和保护测量的理解，这些理论研究的预测将反过来通过实验进行检验。大部分工作将由一组不同的本科生完成，为他们提供了一个培养研究技能和进一步发展科学事业的绝佳机会。本项目将通过实验实现单光子弱保护测量，并通过理论研究补充这些实验。实验方法的特点是使用偏振分量之间的时间差分群延迟（DGD）作为测量“指针”。“该小组将在电信C波段（~1550 nm）构建一个窄带、纯态、单光子源，并使用它首先通过直接测量DGD后的光子到达时间来实现弱偏振测量。这个基本的设置，然后将作为一个新的实验实现的保护测量在时域中，通过利用DGD在一个环路配置来测量光子偏振的期望值的中心构件。光学回路将使团队能够使光子重复通过相同的测量和状态保护阶段，从而实现保护性测量。在该项目的理论部分，该小组将研究保护测量及其性能的几个重要特性，包括：减少状态纯度对测量的影响，光子存活概率以及最终测量的不确定性。这些理论活动将产生模型和预测，可以通过实验进行测试，这将提高我们对保护措施的理解。这个奖项反映了NSF的法定使命，并已被认为是值得通过使用基金会的智力价值和更广泛的影响审查标准进行评估的支持。