* Astronomy

Title: The spine of the swan: A Herschel study of the DR21 ridge and filaments in Cygnus X
Authors: M. Hennemann, F. Motte, N. Schneider, P. Didelon, T. Hill, D. Arzoumanian, S. Bontemps, T. Csengeri, Ph. Andre, V. Konyves, F. Louvet, A. Marston, A. Men'shchikov, V. Minier, Q. Nguyen Luong, P. Palmeirim, N. Peretto, M. Sauvage, A. Zavagno, L. D. Anderson, J.-Ph. Bernard, J. Di Francesco, D. Elia, J. Z. Li, P. G. Martin, S. Molinari, S. Pezzuto, D. Russeil, K. L. J. Rygl, E. Schisano, L. Spinoglio, T. Sousbie, D. Ward-Thompson, G. J. White

In order to characterise the cloud structures responsible for the formation of high-mass stars, we present Herschel observations of the DR21 environment. Maps of the column density and dust temperature unveil the structure of the DR21 ridge and several connected filaments. The ridge has column densities larger than 1e23/cm² over a region of 2.3 pc². It shows substructured column density profiles and branching into two major filaments in the north. The masses in the studied filaments range between 130 and 1400 solar masses whereas the mass in the ridge is 15000 solar masses. The accretion of these filaments onto the DR21 ridge, suggested by a previous molecular line study, could provide a continuous mass inflow to the ridge. In contrast to the striations seen in e.g., the Taurus region, these filaments are gravitationally unstable and form cores and protostars. These cores formed in the filaments potentially fall into the ridge. Both inflow and collisions of cores could be important to drive the observed high-mass star formation. The evolutionary gradient of star formation running from DR21 in the south to the northern branching is traced by decreasing dust temperature. This evolution and the ridge structure can be explained by two main filamentary components of the ridge that merged first in the south.

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Before They Were Stars: New Image Shows Space Nursery

The stars we see today weren't always as serene as they appear, floating alone in the dark of night. Most stars, likely including our sun, grew up in cosmic turmoil - as illustrated in a new image from NASA's Spitzer Space Telescope.
The image shows one of the most active and turbulent regions of star birth in our galaxy, a region called Cygnus X. The choppy cloud of gas and dust lies 4,500 light-years away in the constellation Cygnus the Swan. Cygnus X was named by radio astronomers, since it is one of the brightest radio regions in the Milky Way. (It should not be confused with the black hole Cygnus X-1.)
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