Collaborative Research: GEM: Plasma Transport from the Solar Wind to the Inner Magnetosphere

合作研究：GEM：从太阳风到内磁层的等离子体传输

• 批准号: 0602708
• 负责人: Colby Lemon
• 金额: $ 25万
• 依托单位: Aerospace Corporation
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-08-15 至 2010-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0602708&HistoricalAwards=false
• 关键词: Collaborative; Research; GEM; Plasma; Transport

This project will investigate the physical processes that lead to the transport of solar wind ions from the magnetosheath and into the magnetosphere to form the plasma sheet. Ion distributions in the magnetosheath, tail lobes, tail flanks, and plasma sheet will thus be characterized for different Interplanetary Magnetic Field (IMF) and solar wind conditions. The study will address whether the transport of solar wind ions into the magnetosphere from different locations supply sufficient particles of different energies needed to form the quiescent and storm-time plasma sheet. The effect of changes in the solar wind population on the variance in the plasma sheet will also be examined. The approach will be to develop and use kinetic simulations to study the relevant particle transport processes and to compare the simulation results with published observations from satellites such from Geotail, International Sun-Earth Explorer (ISEE), Active Magnetospheric Particle Tracer Explorers (AMPTE), and Defense Meteorological Satellite Program (DMSP). The model will follow the full particle motion or (where appropriate) the guiding-center drifts of solar-wind ions from the magnetosheath into the magnetosphere. In the magnetosheath, the model will use an analytical magnetic field that reproduces quite well the shape of magnetosheath field lines obtained from gas-dynamic calculations. The magnetosheath electric field is proportional to the cross product of the solar-wind velocity and the magnetic field. Especially for southward IMF, the magnetosheath's magnetic field lines will reconnect with initially closed magnetospheric field lines. The magnetospheric model will use the magnetically and electrically self-consistent Rice Convection Model (RCM-E) with a magnetic field boundary condition that includes the effect of a non-uniform penetration magnetic field. This magnetospheric model maintains internal force balance between the magnetospheric plasma and magnetic field. Use of the RCM-E will allow the calculation of self-consistent distributions of particle flux, plasma pressure, and current density within the magnetosphere (including the tail flanks and plasma sheet). The evolution of the distributions in response to varying solar wind conditions will be studied, and the simulation results will be compared with observations. A significant outcome of this work will be a physical understanding of the relationship between properties of the solar-wind plasma (e.g., velocity and density) and the resulting plasma sheet, which is the main source for the ring current. This would provide a currently missing link for characterizing magnetic storms (and eventually accounting for variations of particle population in the inner magnetosphere) from solar-wind properties and IMF conditions. Such an achievement would be beneficial for understanding and forecasting space weather, and thus for society. A significant portion of the funds for this project are dedicated to support the research training of a UCLA graduate student.

该项目将研究导致太阳风离子从磁鞘进入磁层形成等离子体片的物理过程。因此，离子分布的磁鞘，尾叶，尾翼，等离子体片的特点是不同的行星际磁场（IMF）和太阳风条件。这项研究将探讨太阳风离子从不同地点进入磁层的输送是否提供了形成静止和风暴时等离子体片所需的不同能量的足够粒子。还将研究太阳风种群变化对等离子体片方差的影响。该方法将开发和使用动力学模拟来研究相关的粒子传输过程，并将模拟结果与Geotail、国际日地探测器（ISEE）、主动磁层粒子示踪探测器（AMPTE）和国防气象卫星计划（DMSP）等卫星公布的观测结果进行比较。该模型将遵循完整的粒子运动或（在适当的情况下）从磁鞘到磁层的太阳风离子的引导中心漂移。在磁鞘中，该模型将使用一个分析磁场，该磁场很好地再现了从气体动力学计算中获得的磁鞘场线的形状。磁鞘电场与太阳风速度和磁场的叉积成正比。特别是向南的IMF，磁鞘的磁力线将重新连接到最初关闭的磁层磁力线。磁层模型将使用磁和电自洽的赖斯对流模型（RCM-E），其磁场边界条件包括非均匀穿透磁场的影响。该磁层模型保持了磁层等离子体与磁场之间的内力平衡。使用RCM-E将允许计算磁层（包括尾翼和等离子体片）内粒子通量、等离子体压力和电流密度的自洽分布。将研究分布随太阳风条件变化的演变情况，并将模拟结果与观测结果进行比较。这项工作的一个重要成果将是对太阳风等离子体性质之间关系的物理理解（例如，速度和密度）以及由此产生的等离子体片，这是环电流的主要来源。这将提供一个目前缺失的环节，从太阳风特性和国际货币基金组织的条件来描述磁暴（并最终解释内磁层中粒子数量的变化）。这一成就将有助于了解和预报空间气象，从而造福社会。该项目的资金的很大一部分用于支持加州大学洛杉矶分校研究生的研究培训。