TIMES II: Investigating the Relation Between Turbulence and Star-forming Environments in Molecular Clouds

Abstract

We investigate the effect of star formation on turbulence in the Orion A and Ophiuchus clouds using principal component analysis (PCA). We measure the properties of turbulence by applying PCA on the spectral maps in 13CO, C18O, HCO+ J=1-0, and CS J=2-1. First, the scaling relations derived from PCA of the 13CO maps show that the velocity difference (δ v) for a given spatial scale (L) is the highest in the integral shaped filament (ISF) and L1688, where the most active star formation occurs in the two clouds. The δ v increases with the number density and total bolometric luminosity of the protostars in the sub-regions. Second, in the ISF and L1688 regions, the δ v of C18O, HCO+, and CS are generally higher than that of 13CO, which implies that the dense gas is more turbulent than the diffuse gas in the star-forming regions; stars form in dense gas, and dynamical activities associated with star formation, such as jets and outflows, can provide energy into the surrounding gas to enhance turbulent motions.