Initial conditions for star formation in clusters: physical and kinematical structure of the starless core Oph A-N6

TL;DR

This study uses high-resolution observations to analyze the physical and kinematic structure of the starless core Oph A-N6, revealing its compact size, low turbulence, and potential early star formation activity.

Contribution

It provides detailed physical and kinematic characterization of Oph A-N6, a starless core, using high-resolution submillimeter observations, highlighting its structure, dynamics, and evolutionary status.

Findings

Oph A-N6 is a compact, elongated core with minimal turbulence.

The core's properties are consistent with an isothermal cylinder model.

Evidence suggests Oph A-N6 is a precursor to low-mass star formation.

Abstract

We present high spatial (<300 AU) and spectral (0.07 km/s) resolution Submillimeter Array observations of the dense starless cluster core Oph A-N6, in the 1 mm dust continuum and the 3-2 line of N2H+ and N2D+. The dust continuum observations reveal a compact source not seen in single-dish observations, of size ~1000 AU and mass 0.005-0.01 M\odot. The combined line and single-dish observations reveal a core of size 3000 \times 1400 AU elongated in a NW-SE direction, with almost no variation in either line width or line center velocity across the map, and very small non-thermal motions. The deuterium fraction has a peak value of ~0.15 and is >0.05 over much of the core. The N2H+ column density profile across the major axis of Oph A-N6 is well represented by an isothermal cylinder, with temperature 20 K, peak density 7.1 \times 10^6 cm^{-3}, and N2H+ abundance 2.7 \times 10^{-10}. The mass of Oph A-N6 is estimated to be 0.29 M\odot, compared to a value of 0.18 M\odot from the isothermal cylinder analysis, and 0.63 M\odot for the critical mass for fragmentation of an isothermal cylinder. Compared to isolated low-mass cores, Oph A-N6 shows similar narrow line widths and small velocity variation, with a deuterium fraction similar to "evolved" dense cores. It is significantly smaller than isolated cores, with larger peak column and volume density. The available evidence suggests Oph A-N6 has formed through the fragmentation of the Oph A filament and is the precursor to a low-mass star. The dust continuum emission suggests it may already have begun to form a star.