Context. Low-mass star-forming cores differ from their surrounding molecular cloud in turbulence, shape, and density structure. Aims. We aim to understand how dense cores form out of the less dense cloud material by studying the connection between these two regimes. Methods. We observed the L1517 dark cloud in C18O(1–0), N2H+(J = 1−0), and SO(JN = 32 − 21) with the FCRAO 14 m telescope, and in the 1.2 mm dust continuum with the IRAM 30 m telescope. Results. Most of the gas in the cloud lies in four filaments that have typical lengths of 0.5 pc. Five starless cores are embedded in these filaments and have chemical compositions indicative of different evolutionary stages. The filaments have radial profiles of C18O(1−...
Context. The Pipe nebula is a molecular cloud that lacks star formation feedback and has a...
We examine the conditions under which binary and multiple stars may form out of turbulent molecular ...
The exact process(es) that generate(s) dense filaments which then form prestellar cores within them ...
Context. Core condensation is a critical step in the star-formation process, but it is still poorly ...
Context. Cloud fragmentation into dense cores is a critical step in the process of star formation. A...
Context. Core condensation is a critical step in the star-formation process, but is still poorly cha...
Star formation takes place in dense cores within molecular clouds. These cores are characterised by ...
Context. Nitrogen bearing species, such as NH3, N2H+, and their deuterated isotopologues show enhanc...
Context. Dense molecular filaments are central to the star formation process, but the detailed manne...
The theory of star formation that has developed over the past several decades supposes that dense co...
We carried out an unbiased mapping survey of dense molecular cloud cores traced by the NH3 (1,1) and...
This is the final published version. Available from the American Astronomical Society via the DOI in...
Context. Observations suggest that low-mass stars condense out of dense, relatively isolated, molecu...
Dense molecular cloud cores are studied statistically in nearby ($d \leq 200$ pc) star-forming regi...
Sheet-like clouds are common in turbulent gas and perhaps form via collisions between turbulent gas ...
Context. The Pipe nebula is a molecular cloud that lacks star formation feedback and has a...
We examine the conditions under which binary and multiple stars may form out of turbulent molecular ...
The exact process(es) that generate(s) dense filaments which then form prestellar cores within them ...
Context. Core condensation is a critical step in the star-formation process, but it is still poorly ...
Context. Cloud fragmentation into dense cores is a critical step in the process of star formation. A...
Context. Core condensation is a critical step in the star-formation process, but is still poorly cha...
Star formation takes place in dense cores within molecular clouds. These cores are characterised by ...
Context. Nitrogen bearing species, such as NH3, N2H+, and their deuterated isotopologues show enhanc...
Context. Dense molecular filaments are central to the star formation process, but the detailed manne...
The theory of star formation that has developed over the past several decades supposes that dense co...
We carried out an unbiased mapping survey of dense molecular cloud cores traced by the NH3 (1,1) and...
This is the final published version. Available from the American Astronomical Society via the DOI in...
Context. Observations suggest that low-mass stars condense out of dense, relatively isolated, molecu...
Dense molecular cloud cores are studied statistically in nearby ($d \leq 200$ pc) star-forming regi...
Sheet-like clouds are common in turbulent gas and perhaps form via collisions between turbulent gas ...
Context. The Pipe nebula is a molecular cloud that lacks star formation feedback and has a...
We examine the conditions under which binary and multiple stars may form out of turbulent molecular ...
The exact process(es) that generate(s) dense filaments which then form prestellar cores within them ...