Dynamical processes in nanostructured and low-dimensional magnetic materials

纳米结构和低维磁性材料的动力学过程

• 批准号: 36357-2012
• 负责人: Cottam, Michael
• 金额: $ 1.82万
• 依托单位: University of Western Ontario
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=593001
• 关键词: Dynamical; processes; nanostructured; low; dimensional

The current research into fundamental processes in magnetic materials that have one or more dimensions in the nanometer or submicron ranges is being driven by their immense potential for technological applications in the areas (for example) of new types of magnetic memory, ultrafast switching, and high-frequency devices. This is coupled with recent advances in growth and fabrication techniques that allow a wide variety of nanostructures composed of magnetic elements and their arrays to be reliably produced. Consequently, on the theoretical side there is a pressing need to understand at a fundamental level the dynamical processes taking place within such materials on these small length scales in order to engineer and enhance the properties of the devices and applications, as well as to predict new effects. This provides the primary objective and focus for this proposed program of theoretical research. The calculations will be carried out by using different quantum-mechanical techniques, often in conjunction with numerical simulation methods, and applied to the collective excitations or waves in the materials, e.g., the spin waves (or magnons), sometimes together with the vibrational waves (or phonons) and electronic excitations. Novel effects are expected to arise due to the spatial quantization of these waves confined in the finite materials and due to the presence of multiple surfaces and interfaces. It is known that nanostructured materials may sometimes display novel characteristics that are absent in their bulk constituent materials, as in the phenomenon of giant magnetoresistance for example, and can be utilized as the basis for new technologies. This provides another motivation for this field of research.

目前对具有纳米或亚微米范围内的一个或多个维度的磁性材料的基本过程的研究是由其在新型磁存储器，超快开关和高频器件等领域的技术应用的巨大潜力所驱动的。这与生长和制造技术的最新进展相结合，这些技术允许可靠地生产由磁性元件及其阵列组成的各种各样的纳米结构。因此，在理论方面，迫切需要在基本水平上了解这些小长度尺度上这些材料内发生的动态过程，以便设计和增强器件和应用的性能，以及预测新的效应。这就为本文提出的理论研究方案提供了主要目标和重点。计算将通过使用不同的量子力学技术进行，通常与数值模拟方法结合，并应用于材料中的集体激发或波，例如，自旋波（或磁振子），有时与振动波（或声子）和电子激发一起。由于这些波的空间量子化限制在有限的材料，并由于存在多个表面和界面，预计会出现新的效果。众所周知，纳米结构材料有时可以显示在其本体组成材料中不存在的新特性，例如在巨磁阻现象中，并且可以用作新技术的基础。这为这一领域的研究提供了另一个动力。