Strong Correlations in Cold atoms and Dirac materials

冷原子和狄拉克材料的强相关性

• 批准号: RGPIN-2019-04434
• 负责人: Kennett, Malcolm
• 金额: $ 2.04万
• 依托单位: Simon Fraser University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=682814
• 关键词: Strong; Correlations; Cold; atoms; Dirac

Quantum technologies that involve the storage, transmission and manipulation of quantum information are an important direction for Canadian Physics research in the 21st Century. Many different platforms for these technologies are currently being explored. Two physical systems that have been suggested as possible settings for future quantum technologies are trapped cold atoms and novel electronic phases in quantum materials. In these systems much of the most fundamentally interesting and technologically relevant novel physics is found in regimes where interactions between quantum particles are strong. This motivates my research program, which focuses on developing theoretical techniques to study strongly interacting quantum systems, and applying these methods to specific physical systems of current interest. Two systems I propose to investigate are i) disordered and many body localized (MBL) cold atom systems and ii) fractional quantum Hall states in graphene and generalizations of Dirac fermions.******In order to manipulate quantum information it is necessary to store it - MBL systems: disordered interacting quantum systems which do not equilibrate, have been suggested as possible quantum memories. The physics of MBL is still being established, including whether it can occur in dimensions greater than one, as suggested by recent cold atom experiments. I have developed a theoretical approach to the out of equilibrium dynamics of cold atoms described by the Bose Hubbard model which gives access to physics inaccessible by conventional methods. I will extend this method and apply it to the experimentally realized situation to assess claims of MBL.******The integer and fractional quantum Hall (FQH) effects take place when two dimensional systems, such as graphene, are placed in strong perpendicular magnetic fields. Some FQH states have been suggested as possible candidates for fault tolerant quantum computing. The FQH effect (FQHE) in graphene differs from the FQHE in conventional semiconductor systems due to the relativistic dispersion and internal degrees of freedom (valley and spin) of quasiparticles in graphene. These features, in conjunction with electron interaction induced broken symmetry states, lead to a rich array of possible FQHE states in graphene which are currently not distinguished by experiment. I will develop theory to aid discrimination between different FQHE states. I will also explore generalizations of the Dirac fermions seen in graphene, which may allow for scenarios for materials realizations of relativistic particles that go beyond those accessible in high energy physics.******The results of this research will be timely theoretical contributions to important current problems and high quality training of HQP. Insights from these contributions may have implications for developments in quantum technologies such as quantum simulation using cold atoms, the use of MBL for quantum memories, or platforms for quantum computation.**

涉及量子信息存储、传输和操纵的量子技术是21世纪加拿大物理学研究的重要方向。 目前正在探索这些技术的许多不同平台。 被认为是未来量子技术可能设置的两个物理系统是量子材料中的捕获冷原子和新电子相。 在这些系统中，许多最基本的有趣和技术相关的新物理学都是在量子粒子之间的相互作用很强的情况下发现的。 这激发了我的研究计划，重点是开发理论技术来研究强相互作用的量子系统，并将这些方法应用于当前感兴趣的特定物理系统。 我建议研究的两个系统是i）无序和多体局域（MBL）冷原子系统和ii）石墨烯中的分数量子霍尔态和狄拉克费米子的推广。为了操纵量子信息，有必要存储它- MBL系统：不平衡的无序相互作用量子系统，已被建议作为可能的量子存储器。 MBL的物理学仍在建立中，包括它是否可以发生在大于一维的空间中，正如最近的冷原子实验所表明的那样。 我已经开发了一种理论方法来描述的玻色哈伯德模型，它提供了传统方法无法访问的物理冷原子的平衡动力学。我将扩展这种方法，并将其应用于实验实现的情况，以评估MBL的声明。当二维系统（如石墨烯）被置于强垂直磁场中时，会发生整数和分数量子霍尔（HALL）效应。已经提出了一些可作为容错量子计算的可能候选者。 由于石墨烯中准粒子的相对论色散和内部自由度（谷和自旋），石墨烯中的量子阱效应（量子阱效应）与传统半导体系统中的量子阱效应不同。 这些特征与电子相互作用诱导的对称性破缺态相结合，导致石墨烯中出现了丰富的可能的FQHE态，这些态目前尚未通过实验区分。 我将发展理论来帮助区分不同的亚伯拉罕国家。 我还将探索在石墨烯中看到的狄拉克费米子的一般化，这可能允许材料实现相对论粒子的场景，这些场景超出了高能物理学中可访问的场景。本文的研究成果将为解决当前的重要问题和高质量的HQP培训提供及时的理论贡献。 这些贡献的见解可能对量子技术的发展产生影响，例如使用冷原子的量子模拟，将MBL用于量子存储器或量子计算平台。