Quantum Resource Theories

量子资源理论

• 批准号: RGPIN-2015-05271
• 负责人: Gour, Gilad
• 金额: $ 3.06万
• 依托单位: University of Calgary
• 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=688536
• 关键词: Quantum; Resource; Theories

For any given kind of resource, one needs a theory to answer basic questions such as: which collections of resources can be converted into which others, and what are the ways in which a given conversion can be accomplished? Chemistry fits this mold, as it answers the question of how collections of chemicals available in abundance can be converted to other, more useful, products. Thermodynamics is another example, as it answers questions about how various sorts of non-equilibrium states-thermal, mechanical, chemical, etcetera-can be converted into others, for instance, how useful work can be extracted from a pair of heat baths at different temperatures.****The poster child for the resource-theoretic approach today is entanglement theory. Although the notion of entanglement was introduced in the 1930s, it was not until the mid-nineties that we began to have a proper understanding of entanglement, after it was recognized to be useful for certain quantum information processing protocols. In other words, the turning point occurred when researchers began to study entanglement as a resource. Since then, entanglement theory has found applications not only in quantum computation, cryptography and communication, but in many other areas of physics, including the study of phase transitions, characterizing the ground states of many-body systems, holography in quantum field theories, and the black hole information-loss paradox. Inspired by this success, there are now many other properties of quantum states besides entanglement that are being studied as resources: for instance, the extent to which a state breaks symmetries, the extent to which a state deviates from thermal equilibrium, and the extent to which a quantum state is contextual. ****In addition to the basic questions above, this proposal aims to provide answers to questions such as: How does one measure the quality of different resource states? If one particular resource state cannot be converted to another deterministically, can it be done nondeterministically, and if so with what probability? What if one has access to a catalyst? A particularly fundamental problem is to identify the equivalence classes of states that are reversibly interconvertible in the limit of asymptotically-many copies of the resource and to determine the rates of interconversion. ****Answering these concrete questions typically leads to significant new insights into the nature of the physical or information-theoretic phenomenon in question---entanglement, asymmetry, athermality, etcetera---and provides a framework to organize theoretical results concerning those phenomena. As entanglement theory has demonstrated, the resource-theoretic approach has the capacity to revolutionize the way we think about familiar topics.********

对于任何给定类型的资源，都需要一种理论来回答基本问题，例如：哪些资源集合可以转换为哪些其他资源，以及可以通过哪些方式完成给定的转换？化学符合这种模式，因为它回答了如何将大量可用的化学物质转化为其他更有用的产品的问题。 热力学是另一个例子，因为它回答了各种非平衡状态-热，机械，化学等-如何转换为其他状态的问题，例如，如何从不同温度的一对热浴中提取有用的工作。如今，资源论方法的典型代表是纠缠理论。 虽然纠缠的概念是在20世纪30年代提出的，但直到90年代中期，我们才开始对纠缠有了正确的理解，因为它被认为对某些量子信息处理协议有用。 换句话说，转折点发生在研究人员开始将纠缠作为一种资源进行研究的时候。从那时起，纠缠理论不仅在量子计算、密码学和通信中得到了应用，而且在物理学的许多其他领域也得到了应用，包括相变研究、表征多体系统的基态、量子场论中的全息术和黑洞信息丢失悖论。 受这一成功的启发，除了纠缠之外，现在还有许多其他量子态的性质正在被研究作为资源：例如，状态打破对称性的程度，状态偏离热平衡的程度，以及量子态的上下文程度。* 除上述基本问题外，本建议旨在回答以下问题：如何衡量不同资源状况的质量？如果一个特定的资源状态不能被确定性地转换成另一个，那么它可以被非确定性地转换吗？如果可以，概率是多少？如果有人能接触到催化剂呢？ 一个特别基本的问题是确定的等价类的状态是可逆的相互转换的极限渐近多副本的资源，并确定相互转换的速率。 * 讨论这些具体问题通常会导致对所讨论的物理或信息理论现象的性质的重要新见解-纠缠，不对称，无热性等-并提供一个框架来组织有关这些现象的理论结果。正如纠缠理论所证明的那样，资源理论方法有能力彻底改变我们对熟悉话题的思考方式。