Laboratory Studies of Avalanche Transport in Magnetized Plasmas

磁化等离子体中雪崩传输的实验室研究

• 批准号: 1619505
• 负责人: George Morales
• 金额: $ 25.7万
• 依托单位: University of California-Los Angeles
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2016
• 资助国家: 美国
• 起止时间: 2016-07-01 至 2020-06-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1619505&HistoricalAwards=false
• 关键词: Laboratory; Studies; Avalanche; Transport; Magnetized

The goal of this project is to improve our understanding of avalanches in a plasma, a cloud of ionized gas, that is permeated by a magnetic field. Avalanches are sudden events that cause major changes over an extended region of a physical system. Although the concept is commonly associated with catastrophic "snow avalanches", the general phenomenon occurs widely in both natural and artificial systems. A typical driver and source of energy for an avalanche is a sharp change in one of the parameters that describes the underlying system. This project is a synergistic experimental and theoretical study of avalanches triggered by a steep slope in plasma temperature and density across a magnetic field. This is a situation widely encountered in natural plasmas, such as in magnetic field structures on the Sun and around the Earth, and has to be accounted for in any design of a magnetic fusion device. The project will involve a graduate student who will gain a unique perspective on modern experimental techniques and will also participate in theoretical and numerical modeling work.To date, the majority of experimental information about avalanche transport in a magnetized plasma has been obtained in devices designed for fusion studies. However, due to the complexity of these devices, it has proven difficult to unravel the underlying physical mechanisms of the process. This project aims to significantly expand the experimental knowledge base by exploring the behavior of a well-defined plasma configuration that exhibits repeatable, controllable avalanche events. The data obtained in the experiments will provide quantitative information about the role of self-organized criticality dynamics, the formation and evolution of streamers, the effect of flows and flow shear, and the manifestation of nonlocal transport of both temperature and density. These topics are at the frontier of plasma science and are the subject of numerous ongoing theoretical and computational studies.

这个项目的目标是提高我们对等离子体中雪崩的理解，等离子体是一种电离气体云，被磁场渗透。 雪崩是突然发生的事件，会在物理系统的扩展区域造成重大变化。虽然这一概念通常与灾难性的“雪崩”有关，但这种普遍现象在自然和人工系统中都广泛存在。雪崩的一个典型驱动因素和能量来源是描述底层系统的一个参数的急剧变化。 该项目是一项协同实验和理论研究，研究磁场中等离子体温度和密度的陡坡引发的雪崩。 这是在自然等离子体中广泛遇到的情况，例如在太阳和地球周围的磁场结构中，并且必须在任何磁聚变装置的设计中考虑。该项目将涉及一名研究生，他将获得对现代实验技术的独特视角，并将参与理论和数值模拟工作。迄今为止，有关磁化等离子体中雪崩输运的大多数实验信息已经在为聚变研究设计的设备中获得。然而，由于这些设备的复杂性，已经证明难以解开该过程的潜在物理机制。该项目旨在通过探索具有可重复、可控雪崩事件的定义明确的等离子体配置的行为来显着扩展实验知识库。 在实验中获得的数据将提供有关自组织临界动力学的作用，流光的形成和演变，流量和流量剪切的影响，以及温度和密度的非局部运输的表现形式的定量信息。这些课题处于等离子体科学的前沿，是许多正在进行的理论和计算研究的主题。