Naumkin V N, Zhukhovitskii D I, Molotkov V I, Lipaev A M, Fortov V E, Thomas H M, Huber P, Morfill G E
Joint Institute of High Temperatures, Russian Academy of Sciences, Izhorskaya 13, Bd. 2, 125412 Moscow, Russia.
Research Group Complex Plasma, DLR, Oberpfaffenhofen, 82234 Wessling, Germany.
Phys Rev E. 2016 Sep;94(3-1):033204. doi: 10.1103/PhysRevE.94.033204. Epub 2016 Sep 7.
We propose a method of determination of the dust particle spatial distribution in dust clouds that form in three-dimensional (3D) complex plasmas under microgravity conditions. The method utilizes the data obtained during the 3D scanning of a cloud, and it provides reasonably good accuracy. Based on this method, we investigate the particle density in a dust cloud realized in gas discharge plasma in the PK-3 Plus setup onboard the International Space Station. We find that the treated dust clouds are both anisotropic and inhomogeneous. One can isolate two regimes in which a stationary dust cloud can be observed. At low pressures, the particle density decreases monotonically with the increase of the distance from the discharge center; at higher pressures, the density distribution has a shallow minimum. Regardless of the regime, we detect a cusp of the distribution at the void boundary and a slowly varying density at larger distances (in the foot region). A theoretical interpretation of the obtained results is developed that leads to reasonable estimates of the densities for both the cusp and the foot. The modified ionization equation of state, which allows for violation of the local quasineutrality in the cusp region, predicts the spatial distributions of ion and electron densities to be measured in future experiments.
我们提出了一种确定在微重力条件下三维(3D)复杂等离子体中形成的尘埃云内尘埃颗粒空间分布的方法。该方法利用了对尘埃云进行三维扫描期间获得的数据,并且具有相当不错的精度。基于此方法,我们研究了国际空间站上PK - 3 Plus装置中气体放电等离子体所形成尘埃云中的颗粒密度。我们发现所处理的尘埃云既具有各向异性又不均匀。可以分离出两种能观测到稳定尘埃云的状态。在低压下,颗粒密度随着与放电中心距离的增加而单调降低;在较高压力下,密度分布有一个较浅的最小值。无论处于哪种状态,我们在空洞边界处检测到分布的一个尖点,并且在较大距离处(在脚部区域)密度变化缓慢。对所得结果进行了理论解释,从而对尖点和脚部的密度得出了合理估计。修正的电离状态方程考虑了尖点区域局部准中性的破坏,预测了未来实验中要测量的离子和电子密度的空间分布。