Chemical differentiation in regions of high-mass star formation I. CS, dust and N2H^+ in southern sources

TL;DR

This study compares the distributions of CS, N2H+, and dust in high-mass star-forming cores, revealing chemical differentiation, clumpiness, and correlations with physical properties through molecular mapping and modeling.

Contribution

It provides new insights into the spatial variations and chemical abundances of CS and N2H+ in dense cores, using combined observational and modeling approaches.

Findings

CS and continuum peaks are closely aligned in most cores.

N2H+ abundance decreases near CS peaks, indicating chemical differentiation.

Mass estimates suggest small-scale clumpiness of the cores.

Abstract

Aims. Our goals are to compare the CS, N2H+ and dust distributions in a representative sample of high-mass star forming dense cores and to determine the physical and chemical properties of these cores. Methods. We compare the results of CS(5-4) and 1.2 mm continuum mapping of twelve dense cores from the southern hemisphere presented in this work, in combination with our previous N2H+(1-0) and CS(2-1) data. We use numerical modeling of molecular excitation to estimate physical parameters of the cores. Results. Most of the maps have several emission peaks (clumps). We derive basic physical parameters of the clumps and estimate CS and N2H+ abundances. Masses calculated from LVG densities are higher than CS virial masses and masses derived from continuum data, implying small-scale clumpiness of the cores. For most of the objects, the CS and continuum peaks are close to the IRAS point source positions. The CS(5-4) intensities correlate with continuum fluxes per beam in all cases, but only in five cases with the N2H+(1-0) intensities. The study of spatial variations of molecular integrated intensity ratios to continuum fluxes reveals that I(N2H+)/F{1.2} ratios drop towards the CS peaks for most of the sources, which can be due to a N2H+ abundance decrease. For CS(5-4), the I(CS)/F{1.2} ratios show no clear trends with distance from the CS peaks, while for CS(2-1) such ratios drop towards these peaks. Possible explanations of these results are considered. The analysis of normalized velocity differences between CS and N2H+ lines has not revealed indications of systematic motions towards CS peaks.