Chemical segregation toward massive hot cores: The AFGL2591 star forming   region

I. Jimenez-Serra (1); Q. Zhang (1); S. Viti (2); J. Martin-Pintado (3); and W.-J. de Wit (4) ((1) Harvard-Smithsonian Center for Astrophysics; USA,; (2) University College London; UK; (3) Centro de Astrobiologia (INTA/CSIC),; Spain; (4) European Southern Observatory; Chile)

arXiv:1204.6335·astro-ph.SR·June 4, 2015

Chemical segregation toward massive hot cores: The AFGL2591 star forming region

I. Jimenez-Serra (1), Q. Zhang (1), S. Viti (2), J. Martin-Pintado (3), and W.-J. de Wit (4) ((1) Harvard-Smithsonian Center for Astrophysics, USA,, (2) University College London, UK, (3) Centro de Astrobiologia (INTA/CSIC),, Spain, (4) European Southern Observatory, Chile)

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TL;DR

This study reveals a unique chemical segregation within the AFGL2591 hot core, showing concentric shells of different molecules at sub-3000 AU scales, linked to UV photo-dissociation and high-temperature chemistry.

Contribution

First observation of chemical segregation in a hot core at <3000 AU, demonstrating concentric molecular shells and their relation to core chemistry and kinematics.

Findings

01

Distinct molecular shells with specific species distributions

02

Temperature gradient consistent with prior models

03

Keplerian-like rotation around a 40 solar mass star

Abstract

We present high angular resolution observations (0.5"x0.3") carried out with the Submillimeter Array (SMA) toward the AFGL2591 high-mass star forming region. Our SMA images reveal a clear chemical segregation within the AFGL2591 VLA 3 hot core, where different molecular species (Type I, II and III) appear distributed in three concentric shells. This is the first time that such a chemical segregation is ever reported at linear scales <3000 AU within a hot core. While Type I species (H2S and 13CS) peak at the AFGL2591 VLA 3 protostar, Type II molecules (HC3N, OCS, SO and SO2) show a double-peaked structure circumventing the continuum peak. Type III species, represented by CH3OH, form a ring-like structure surrounding the continuum emission. The excitation temperatures of SO2, HC3N and CH3OH (185+-11 K, 150+-20 K and 124+-12 K, respectively) show a temperature gradient within the AFGL2591…

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