We utilize the extensive data sets available for the Perseus molecular cloud to analyze the relationship between the kinematics of small-scale dense cores and the larger structures in which they are embedded. The kinematic measures presented here can be used in conjunction with those discussed in our previous work as strong observational constraints that numerical simulations (or analytic models) of star formation should match. We find that dense cores have small motions with respect to the 13CO gas, about one third of the 13CO velocity dispersion along the same line of sight. Within each extinction region, the core-to-core velocity dispersion is about half of the total (13CO) velocity dispersion seen in the region. Large-scale velocity gradients account for roughly half of the total velocity dispersion in each region, similar to what is predicted from large-scale turbulent modes following a power spectrum of P(k) ∝ k –4.
展开▼
机译:我们利用可用于Perseus分子云的大量数据集来分析小规模致密核运动学与嵌入它们的较大结构之间的关系。此处介绍的运动学度量可以与我们先前工作中讨论的运动学度量结合使用,作为恒星形成的数值模拟(或分析模型)应匹配的强烈观测约束。我们发现,密集的岩心相对于13CO气体的运动很小,大约是13CO沿同一视线速度散布的三分之一。在每个消光区域内,芯间速度色散约为该区域内总(13CO)速度色散的一半。大规模速度梯度大约占每个区域总速度弥散的一半,这与根据功率谱P(k)∝ k –4的大规模湍流模式所预测的相似。
展开▼
