Studies of Ultracold Plasma

超冷等离子体的研究

• 批准号: 1004242
• 负责人: Steven Rolston
• 金额: $ 46.3万
• 依托单位: University of Maryland, College Park
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-09-01 至 2015-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1004242&HistoricalAwards=false
• 关键词: Studies; Ultracold; Plasma

Plasma is by far the most common form of matter in the universe, but is usually quite hot, especially when created in the laboratory. The researchers of this project developed a technique that starts with laser-cooled atoms to produce ultracold plasmas, with temperatures that they have measured to less than 1 K. This work will continue to study the properties of ultracold plasmas, as they expand into vacuum, and when they are confined in two and three dimensions with magnetic fields. The researchers will investigate how magnetic fields modify the collective properties of the plasma and how dynamics are changed. The researchers will develop techniques to measure the distribution of highly excited atoms created by the plasma to test the theory at low temperatures, which bears on efforts to trap and study antihydrogen atoms. They will study the evaporation of electrons from the plasma, which will provide insight into the basic physics of non-equilibrium systems, which occur quite often in nature.This research is exploratory, investigating regimes of physical system that have not previously been explored, or theoretically treated. It resides at the boundary between atomic physics and plasma physics. Greater understanding of these systems may have relevance for astrophysical processes occurring in the interior of planets and stars, as well as for inertial confinement fusion. They also provide a testing ground for state-of-the-art molecular dynamics simulations, which have applications in many areas of physics and technology, including national security. Graduate and undergraduate students will be trained in state-of-the-art optical techniques, along with gaining experience with high vacuum, analog, RF, and digital electronics, and computer-based data acquisition. They will be in an environment that exposes them to a wide variety of physics.

等离子体是迄今为止宇宙中最常见的物质形式，但通常非常热，尤其是在实验室中产生时。 该项目的研究人员开发了一种技术，从激光冷却原子开始产生超冷等离子体，他们测量的温度低于 1 K。这项工作将继续研究超冷等离子体在膨胀到真空中时的特性，当它们被磁场限制在二维和三维空间时。研究人员将研究磁场如何改变等离子体的集体特性以及动力学如何改变。研究人员将开发测量等离子体产生的高激发原子分布的技术，以在低温下测试该理论，这有助于捕获和研究反氢原子。 他们将研究电子从等离子体中的蒸发，这将有助于深入了解自然界中经常发生的非平衡系统的基本物理学。这项研究是探索性的，研究以前从未探索过的物理系统的状态，或者理论上治疗。 它位于原子物理学和等离子体物理学之间的边界。 对这些系统的更多了解可能与行星和恒星内部发生的天体物理过程以及惯性约束聚变有关。 它们还为最先进的分子动力学模拟提供了一个试验场，这些模拟在物理和技术的许多领域都有应用，包括国家安全。 研究生和本科生将接受最先进的光学技术培训，并获得高真空、模拟、射频和数字电子以及基于计算机的数据采集方面的经验。 他们将处于一个使他们接触各种物理的环境中。