Theoretical investigations in superconductivity

超导理论研究

• 批准号: 157475-2006
• 负责人: Nicol, Elisabeth
• 金额: $ 2.72万
• 依托单位: University of Guelph
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2006
• 资助国家: 加拿大
• 起止时间: 2006-01-01 至 2007-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=336548
• 关键词: Theoretical; investigations; superconductivity

Superconductivity is a phenomenon occurring at very low temperatures approaching absolute zero (-273C) where certain materials lose all resistance to the flow of electrical current and become perfect conductors. First discovered in 1911, superconductivity continues to provide  major theoretical and experimental challenges to the physics and materials research communities. In recent times, new classes of superconductors have been discovered at a phenomenal rate. A major breakthrough came in 1986 with the discovery of a new family of materials which superconduct at much higher temperatures than previously known. This mobilized an unprecedented activity amongst scientists around the world due to potential for applications and improvements in existing applications using superconductivity, such as the high speed MAGLEV (Magnetic Levitation) train being implemented in Japan, superconducting cables for power transmission, microwave filters for communications, industrial magnets, and medical diagnosis with MRI (Magnetic Resonance Imaging). Many of these new superconductors are highly unconventional, posing unique difficulties with the conventional theory of superconductivity, and likely will require a new paradigm. It is expected that study of these materials will not only provide guidance as to how to develop new materials and improved properties for applications, but will also lead to new insights into fundamental science. I have carried out research in theoretical superconductivity to further understanding of this phenomenon in both conventional and unconventional superconductors. The focus of my work is three-fold: 1) to calculate properties of superconductors for comparison with experiment; 2) to provide theoretical support for experimental groups studying superconductors; and 3) to study new mechanisms for elucidating the nature of superconductivity in novel exotic superconductors, such as the high temperature superconductors. One of the main goals of this research is to use model calculations in conjunction with experiment to give important insight into the underlying mechanism of superconductivity.

超导性是在接近绝对零度（-273 ℃）的极低温度下发生的现象，其中某些材料失去对电流流动的所有阻力并成为完美的导体。超导性于1911年首次被发现，它继续为物理和材料研究界提供重大的理论和实验挑战。近年来，新的超导体以惊人的速度被发现。1986年，一个重大的突破出现了，发现了一种新的材料家族，这种材料在比以前已知的温度高得多的温度下超导。这在世界各地的科学家中引发了前所未有的活动，因为超导性的应用潜力和现有应用的改进，例如日本正在实施的高速磁悬浮列车，用于电力传输的超导电缆，用于通信的微波滤波器，工业磁体和MRI（磁共振成像）的医疗诊断。这些新的超导体中有许多是高度非常规的，对传统的超导理论造成了独特的困难，可能需要一个新的范式。预计对这些材料的研究不仅将为如何开发新材料和改进应用性能提供指导，而且还将导致对基础科学的新见解。我进行了理论超导性的研究，以进一步了解这种现象在传统和非传统的超导体。我的工作重点有三个方面：1）计算超导体的性质，与实验进行比较; 2）为研究超导体的实验组提供理论支持; 3）研究新的机制，以阐明新的奇异超导体（如高温超导体）的超导性。这项研究的主要目标之一是将模型计算与实验结合起来，以深入了解超导性的潜在机制。