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Resolving the Vela C ridge with P-ArTeMiS and Herschel

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arxiv 1211.0275 v1 pith:IJNISMSV submitted 2012-11-01 astro-ph.SR astro-ph.GA

Resolving the Vela C ridge with P-ArTeMiS and Herschel

classification astro-ph.SR astro-ph.GA
keywords ridgeherschelvelacentraldensityobservationsbeltemis
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We present APEX/P-ArT\'eMiS 450\mu m continuum observations of RCW 36 and the adjacent ridge, a high-mass high-column density filamentary structure at the centre of the Vela C molecular cloud. These observations, at higher resolution than Herschel's SPIRE camera, reveal clear fragmentation of the central star-forming ridge. Combined with PACS far-infrared and SPIRE sub-millimetre observations from the Herschel HOBYS project we build a high resolution column density map of the region mapped with P-ArT\'eMiS. We extract the radial density profile of the Vela C ridge which with a ~ 0.1pc central width is consistent with that measured for low-mass star-forming filaments in the Herschel Gould Belt survey. Direct comparison with Serpens South, of the Gould Belt Aquila complex, reveals many similarities between the two regions. Despite likely different formation mechanisms and histories, the Vela C ridge and Serpens South filament share common characteristics, including their filament central widths.

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  1. Evolution of compressed clouds formed by filament coalescence. I. Oblique collisions

    astro-ph.GA 2026-05 unverdicted novelty 5.0

    Oblique filament collisions lead to gravitational collapse of the compressed cloud when post-collision |gravitational energy| exceeds kinetic plus thermal plus magnetic energies, with lower angles and lower velocities...