Collaborative Research: Topological States and Quantum Information in Semiconductors and Cold Atom Superfluids

合作研究：半导体和冷原子超流体中的拓扑态和量子信息

• 批准号: 1104546
• 负责人: Chuanwei Zhang
• 金额: $ 15万
• 依托单位: Washington State University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2011
• 资助国家: 美国
• 起止时间: 2011-08-15 至 2012-09-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1104546&HistoricalAwards=false
• 关键词: Collaborative; Research; Topological; States; Quantum

This program is for theoretical research and education for a revolutionary recent idea for quantum computation, known as topological quantum computation (TQC). TQC has been shown to be free of many of the serious problems facing other more conventional means of quantum computation. Although this has been proved as a point of principle in mathematics, suitable platforms to support TQC are yet to be found in nature and this program addresses this issue. In the absence of suitable natural platforms, the PIs will devise practical methods to artificially induce the desired properties for TQC on cold atom systems and semiconductors. They will also develop the appropriate TQC architectures on the considered physical systems and study the fundamental limits on quantum coherence due to thermal and disorder effects in the various TQC platforms. In contrast to other, more "conventional" means of quantum computation, TQC is inherently fault-tolerant and scalable. The studies performed in this program, consisting of TQC platforms, limits on quantum coherence, and suitable computation architectures, will result in TQC being one step closer to experimental realization. The program will seek to realize synthetic TQC platforms and to design appropriate TQC architectures. A deep theoretical understanding of the fundamental limits of quantum protection in these systems would not only pioneer coherent control of quantum information, but would also influence the basic strongly-correlated atomic and electronic physics in the classroom. The latter has broader impact beyond the field of quantum computation. This research will foster training of graduate students at both Washington State University and Clemson University at the interface of quantum information science, atomic physics, condensed matter physics, and numerical methods. The diverse nature of this training will prepare the students in a multidisciplinary employment market. This research will also help both universities update the physics curriculum to reflect the modern trends in science and technology. Per NSF mission of promoting science and engineering education, these integrated research and education activities will promote the participation of undergraduate and graduate students from the state of Washington and the EPSCoR state of South Carolina in science and technology, and will improve the two states' long-term infrastructure.

该计划用于理论研究和教育，用于革命性的量子计算的革命性思想，称为拓扑量子计算（TQC）。 TQC已被证明没有其他更常规的量子计算手段面临的许多严重问题。尽管这已被证明是数学原则的重点，但在自然界中尚未找到支持TQC的合适平台，并且该计划解决了这个问题。在没有合适的天然平台的情况下，PIS将设计实用方法来人为地诱导TQC在冷原子系统和半导体上的所需特性。他们还将在考虑的物理系统上开发适当的TQC体系结构，并研究由于各种TQC平台中的热和疾病效应而引起的量子相干性的基本限制。与其他更“常规”的量子计算手段相比，TQC本质上是容易且可扩展的。在该程序中进行的研究，包括TQC平台，量子相干性的限制和合适的计算体系结构，将导致TQC更接近实验实现。该计划将寻求实现合成的TQC平台并设计适当的TQC架构。对这些系统中量子保护的基本局限性的深刻理论理解不仅会先驱对量子信息的相干控制，而且还会影响教室中基本的强烈相关的原子和电子物理学。后者在量子计算领域中具有更大的影响。这项研究将在华盛顿州立大学和克莱姆森大学的研究生培训量子科学，原子物理学，冷凝物物理学和数值方法的培训。这项培训的多样性将使学生在多学科就业市场中做好准备。这项研究还将帮助两家大学更新物理课程，以反映科学和技术的现代趋势。根据NSF促进科学和工程教育的使命，这些综合的研究和教育活动将促进来自华盛顿州和南卡罗来纳州EPSCOR州科学技术的本科生和研究生的参与，并将改善这两个州的长期基础设施。