Lightning Initiation and Propagation with an Advanced Computer Model and Code

使用先进的计算机模型和代码进行闪电的引发和传播

• 批准号: 1728217
• 负责人: Ningyu Liu
• 金额: $ 29.49万
• 依托单位: University of New Hampshire
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2016
• 资助国家: 美国
• 起止时间: 2016-11-14 至 2018-12-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1728217&HistoricalAwards=false
• 关键词: Lightning; Initiation; Propagation; Advanced; Computer

This award will allow for the investigation of the initiation and propagation of lightning through developing an advanced computer model and code, performing numerical simulations, and conducting theoretical analysis. How lightning originates inside thunderclouds and propagates through air is a longstanding fundamental problem in the field of atmospheric electricity. It has been suggested that there are three critical steps in lightning initiation and propagation: initiation and propagation of streamers that are relatively cold plasma channels, transition from streamers to bright, hot, highly conductive leaders, and propagation of leaders. Recent studies have firmly established that streamers can be initiated from thundercloud hydrometeors subject to the maximum thundercloud electric field measured so far. However, the other two steps of lightning initiation and propagation remain poorly understood. It is unknown whether the streamers originating from thundercloud hydrometeors will be able to generate the first leader at their stem, and if they can, how the streamer-to-leader transition occurs and how this transition depends on thundercloud conditions such as thundercloud charge and field. In addition, experiments and observations have indicated that the most common type of lightning leaders called negative leaders develops in a stepping manner. Perhaps being one of the most "mysterious" phenomena in atmospheric electricity, luminous blob structures known as "space stems" are found to appear in front of the negative leader tip and they develop into bidirectional "space leaders" to support the stepping propagation of negative leaders. There is currently no theory that offers an explanation for the formation of space stems and space leaders.The objective of the project is to develop an advanced computer model and code to study lightning initiation and propagation. A three-dimensional computer code, that includes all required plasma kinetic and gas dynamic components to self-consistently model streamer propagation, leader initiation, and formation of space stems and space leaders, will be developed. With the developed model and code, the following research activities will be conducted: (1) investigating the characteristics of long (10 cm) streamers propagating in electric fields near or greater than the streamer propagation threshold fields, (2) studying the initiation of streamers from the trail of an expanding, accelerating streamer of opposite polarity and its implications for the formation of space stems and space leaders, and (3) investigating air heating in the channels of streamers originating from hydrometeors, the possibility of the formation of the first leader channel at their stem, and the formation of space stems and space leaders in front of a negative leader.Intellectual Merit :Intellectual merit of these activities is defined by the direct attack on one of the most challenging problems in lightning research and by the investigation of the least-understood processes of lightning. With the recent development of lightning experiments, observations and theories, great progress has been made in lightning research. The work will fill a gap in the knowledge of electrical breakdown processes of lightning to further advance the current understanding of lightning, and it will also result in development of an advanced computer model and code that will be used for lightning research for years to come.Broader Impacts :Broader impacts of these activities include: (1) advancement of scientific knowledge in a subject that may contribute to improving the current practice and/or developing new techniques to better forecast severe weather, especially under the increasing pressure of adapting to climate change, (2) improvement of science, technology, engineering, and mathematics (STEM) education, (3) development of STEM workforce, (4) participation of women and underrepresented minorities in scientific research, (5) development of simulation software and approaches that will benefit research work in other areas such as laboratory plasma discharges and high-altitude sprites and jets, and (6) broad dissemination of the results in the forms of refereed publications, conference presentations, public lectures and press releases.

该奖项将允许通过开发先进的计算机模型和代码，进行数值模拟和进行理论分析来调查闪电的启动和传播。闪电是如何在雷暴云中产生并在空气中传播的，这是大气电学领域长期存在的基本问题。有人建议，有三个关键的步骤，在闪电的启动和传播：启动和传播的流光是相对冷的等离子体通道，过渡从流光明亮，热，高导电的领导人，和领导人的传播。最近的研究已经确定，流光可以启动从雷暴云水凝物受最大的雷暴云电场测量到目前为止。然而，闪电的启动和传播的其他两个步骤仍然知之甚少。目前尚不清楚源自雷暴云水流星的彩带是否能够在其茎部产生第一个先导，如果可以，彩带到先导的转变如何发生以及这种转变如何取决于雷暴云条件，例如雷暴云电荷和场。此外，实验和观察表明，最常见的闪电先导类型称为负先导，以步进方式发展。也许是大气电中最“神秘”的现象之一，被称为“空间茎”的发光斑点结构被发现出现在负先导尖端的前面，它们发展成双向的“空间先导”，以支持负先导的步进传播。目前还没有理论能够解释空间茎和空间先导的形成，该项目的目标是开发一种先进的计算机模型和代码，以研究闪电的产生和传播。将开发一个三维计算机代码，其中包括所有需要的等离子体动力学和气体动力学组件，以自洽地模拟流光传播、先导启动和空间茎和空间先导的形成。利用开发的模型和代码，将开展以下研究活动：（1）研究在接近或大于流光传播阈值场的电场中传播的长（10 cm）流光的特性，（2）研究从相反极性的膨胀、加速流光的尾迹开始的流光及其对空间茎和空间先导形成的影响，（3）研究由水凝物产生的流光通道中的空气加热，在其干处形成第一个先导通道的可能性，以及在负先导前面形成空间干和空间先导。智力价值：这些活动的智力价值是通过对闪电研究中最具挑战性的问题之一的直接攻击和对闪电最不了解的过程的调查来定义的。近年来，随着闪电实验、观测和理论的发展，闪电研究取得了很大进展。这项工作将填补闪电电击穿过程知识的空白，进一步提高目前对闪电的认识，还将导致开发一种先进的计算机模型和代码，用于未来几年的闪电研究。更广泛的影响：这些活动的更广泛影响包括：（1）在某一学科中提高科学知识，有助于改进当前的做法和/或开发新技术，以更好地预报恶劣天气，特别是在适应气候变化的压力越来越大的情况下，（2）改善科学、技术、工程和数学（STEM）教育，（3）发展STEM劳动力，（4）妇女和代表性不足的少数民族参与科学研究，（5）开发模拟软件和方法，这将有利于其他领域的研究工作，如实验室等离子体放电和高空精灵和喷流，以及（6）以参考出版物、会议介绍、公开讲座和新闻稿的形式广泛传播成果。