DECOHERENCE and DISENTANGLEMENT in MACROSCOPIC SYSTEMS

宏观系统中的退相干和解缠结

• 批准号: RGPIN-2019-05582
• 负责人: Stamp, Philip
• 金额: $ 2.48万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 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=714287
• 关键词: DECOHERENCE; DISENTANGLEMENT; MACROSCOPIC; SYSTEMS

Physics is currently built on Quantum Mechanics, which describes small systems, and General Relativity, which describes massive bodies. Each theory has had extraordinary success. Until now it has been impossible to confront them experimentally. In recent years experiments have pushed Quantum Mechanics into the macroscopic realm. Quantum computers - large arrays of 'qubits' made from either solid-state materials or atomic spins - involve macroscopic numbers of atoms. The biggest problem confronting quantum computation is 'decoherence', ie., the mechanism whereby the delicate correlations between qubits are destroyed by the environment around them, ruining the computation. Thus we need a better understanding of the mechanisms involved in decoherence, and how to suppress them. Decoherence mechanisms are also linked to fundamental questions in physics. Experiments involving quantum superpositions in optomechanical devices will soon be possible with masses larger than the Planck mass of 20 micrograms. These will test key features of quantum gravity - and reveal whether either quantum mechanics or General Relativity breaks down. Some argue that an 'intrinsic decoherence' mechanism in Nature will then intervene; others that decoherence may lead to the emergence of classical physics. This project will develop a theory of the dynamics of decoherence mechanisms, for quantum computation and for tests of quantum gravity. The mechanisms include conventional couplings to photons, phonons, electrons, defects, nuclear and paramagnetic impurities, and gravitational degrees of freedom, as well as more exotic mechanisms. The 'conventional' theory will be applied to quantum computation designs involving arrays of spins in semiconductors as well as in certain rare earth and transition metal systems. It will also be used to look at conventional gravitational decoherence mechanisms, relevant to gravitational wave detectors. The more exotic mechanisms include the recent 'correlated worldline' theory of quantum gravity, as well as semiclassical theories of gravity - these theories, and the predicted breakdown of quantum mechanics caused by gravity, will be tested on optomechanical systems. Conventional decoherence for these systems will also be calculated, to separate this from the exotic mechanisms. The most obvious spinoffs/outcomes will be (i) the ability to suppress decoherence in quantum computation - such results are crucial to the design of practical quantum computers - and (ii) quantitative predictions for fundamental experiments in quantum gravity. Other spinoffs will include a better understanding of quantum phase transitions (strongly influenced by decoherence), of great interest for the theory of strongly-correlated condensed matter systems. The most obvious benefit to Canada is in practical quantum computation development - a key future technology, where research like this will be essential.

物理学目前建立在量子力学和广义相对论的基础上，量子力学描述了小系统，广义相对论描述了大质量物体。每一种理论都取得了非凡的成功。到目前为止，还不可能在实验上对抗它们。 近年来，实验将量子力学推向了宏观领域。量子计算机--由固态材料或原子自旋制成的大型“量子比特”阵列--涉及宏观数量的原子。量子计算面临的最大问题是“退相干”，即，量子位之间的微妙相关性被周围环境破坏的机制，破坏了计算。因此，我们需要更好地了解退相干的机制，以及如何抑制它们。 退相干机制也与物理学中的基本问题有关。在光机械装置中进行量子叠加的实验，很快就可以实现质量大于普朗克质量20微克的实验。这些将测试量子引力的关键特征，并揭示量子力学或广义相对论是否崩溃。一些人认为自然界中的“内在退相干”机制会介入;另一些人认为退相干可能导致经典物理学的出现。 这个项目将为量子计算和量子引力的测试发展退相干机制的动力学理论。这些机制包括传统的耦合到光子，声子，电子，缺陷，核和顺磁杂质，和重力自由度，以及更奇特的机制。“传统”理论将应用于量子计算设计，涉及半导体以及某些稀土和过渡金属系统中的自旋阵列。它也将被用来研究与引力波探测器相关的传统引力退相干机制。 更奇特的机制包括最近的量子引力的“相关世界线”理论，以及引力的半经典理论-这些理论，以及由引力引起的量子力学的预测崩溃，将在光机系统上进行测试。这些系统的常规退相干也将被计算，以将其与奇异机制分开。 最明显的副产品/成果将是（i）抑制量子计算中退相干的能力-这些结果对实用量子计算机的设计至关重要-以及（ii）量子引力基础实验的定量预测。其他附带成果将包括更好地理解量子相变（强烈受退相干影响），这对强相关凝聚态系统理论非常感兴趣。 对加拿大来说，最明显的好处是实际的量子计算开发-这是一项关键的未来技术，像这样的研究将是必不可少的。