Collaborative Research: Understanding Sheaths and Pre-Sheaths in Magnetized and Unmagnetized Plasmas

合作研究：了解磁化和非磁化等离子体中的鞘和预鞘

• 批准号: 1464741
• 负责人: Noah Hershkowitz
• 金额: $ 36万
• 依托单位: University of Wisconsin-Madison
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2015
• 资助国家: 美国
• 起止时间: 2015-09-01 至 2019-02-28
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1464741&HistoricalAwards=false
• 关键词: Collaborative; Research; Understanding; Sheaths; Pre

This project will investigate the physical properties of a near-surface layer of a plasma, a plasma sheath, which forms when a solid body is placed into a plasma. Plasmas are gases consisting of free ions and electrons; they are abundant in the universe, have many industrial applications and are the critical component of controlled fusion research. Nearly a half of the manufacturing steps necessary to fabricate a computer microprocessor employ plasmas. The interaction of plasmas with materials depends on the region close to the surfaces known as the plasma sheath. Better understanding of sheaths will lead to improved microprocessor fabrications and might be essential in achieving controlled fusion. The tabletop experiments employed in this study are also ideal for, and will greatly contribute to, training of students in the field of plasma physics and other STEM fields. Proposed new and continuing experiments are aimed at establishing the basic properties of sheaths and associated presheaths, which accelerate ions to the sheath. The specific questions that will be addressed are: 1. What are the details of the newly recognized instability-enhanced collisional friction? 2. What happens to the anisotropy of ion velocity distribution functions (IVDFs) along the presheath and at the sheath-edge? 3. Why do experimental transverse IVDF results differ from simulations? 4. Are the ions in three species weakly collisional plasmas all lost at the system sound velocity when they have comparable densities? 5. Are there separate presheaths associated with ion-neutral collisions and oblique magnetic fields? 6. How do sheaths and presheaths at dielectric and mixed boundaries differ from those at conductors? 7. Does the sheath disappear or not when a small electrode is biased to the plasma potential? Coordinated studies of these phenomena will be carried out at the University of Wisconsin-Madison and the University of San Diego. Experiments will determine the presheath and sheath plasma potential profiles and the resulting IVDFs associated with ion acceleration. Most of the experiments will be carried out in Madison and led by the PI Prof. Noah Hershkowitz. Laser induced fluorescence (LIF) diagnostic development will be carried out on both campuses and led by the Co-PI Prof. Greg Severn. Plasma parameters will be determined with two or more techniques, e.g. combinations of emissive probes, LIF, Langmuir probes, ion acoustic wave measurements, and optical emission spectroscopy. Experiments will employ hot filament multi-dipole, capacitive, inductive, and helicon sources currently in operation.

这个项目将研究等离子体近表面层的物理特性，等离子体鞘层，当固体被放入等离子体时形成。等离子体是由自由离子和电子组成的气体;它们在宇宙中丰富，具有许多工业应用，并且是受控聚变研究的关键组成部分。制造计算机微处理器所需的近一半制造步骤都使用等离子体。等离子体与材料的相互作用取决于被称为等离子体鞘的靠近表面的区域。更好地了解鞘将导致改进的微处理器制造，并可能是必不可少的，在实现受控聚变。在这项研究中采用的桌面实验也是理想的，并将大大有助于，在等离子体物理和其他STEM领域的学生的培训。拟议的新的和持续的实验旨在建立鞘和相关的预鞘，加速离子鞘的基本属性。将讨论的具体问题是：1。新认识到的不稳定性增强碰撞摩擦的细节是什么？2.离子速度分布函数（IVDFs）沿着鞘层和鞘层边缘的各向异性发生了什么变化？3.为什么实验横向IVDF结果与模拟不同？4.当密度相当时，三种弱碰撞等离子体中的离子是否都在系统声速下损失？5.是否存在与离子中性碰撞和倾斜磁场有关的单独的前鞘？6.介电和混合边界处的鞘层和预鞘层与导体处的鞘层和预鞘层有何不同？7.当小电极偏置到等离子体电位时，鞘层是否消失？将在威斯康星大学麦迪逊分校和圣地亚哥大学对这些现象进行协调研究。实验将确定鞘前和鞘等离子体电位分布以及与离子加速相关的所得IVDF。大部分实验将在麦迪逊进行，由PI教授Noah Hershkowitz领导。激光诱导荧光（LIF）诊断开发将在两个校区进行，并由联合PI教授Greg塞文领导。等离子体参数将用两种或更多种技术确定，例如发射探针、LIF、朗缪尔探针、离子声波测量和光学发射光谱的组合。实验将采用热灯丝多偶极，电容，电感，和螺旋源目前正在运作。