MAJORS II: HCO+& HCN Abundances in W40

Ren\'e Plume; David J. Eden; Malcolm J. Currie; Lawrence K. Morgan; Xue-Jian Jiang; James DiFrancesco; Masatoshi Imanishi; Kee-Tae Kim; Tie Liu; Raffaele Rani; Alessio Traficante; Jane Cohen; Neal J. Evans II; Luis C. Ho; Eun Jung Chung; Sihan Jiao; Chang Won Lee; Dana Alina; Toby Moore; Jonathan M. C. Rawlings; Florian Kirchschlager; Sudeshna Patra; Andrew J. Rigby; Hsien Shang; Jihye Hwang; Patricio Sanhueza; Mark G. Rawlings; Kianoosh Tahani; Junfeng Wang; Kate Pattle; James S. Urquhart; Quang Nguyen-Luong; Sarah E. Ragan; Yang Su; Xindi Tang; Agata Karska; and Michael G. Burton

arXiv:2601.19971·astro-ph.GA·January 29, 2026

MAJORS II: HCO+& HCN Abundances in W40

Ren\'e Plume, David J. Eden, Malcolm J. Currie, Lawrence K. Morgan, Xue-Jian Jiang, James DiFrancesco, Masatoshi Imanishi, Kee-Tae Kim, Tie Liu, Raffaele Rani, Alessio Traficante, Jane Cohen, Neal J. Evans II, Luis C. Ho, Eun Jung Chung, Sihan Jiao, Chang Won Lee, Dana Alina

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TL;DR

This study measures HCN and HCO+ abundances in the W40 star-forming region using radiative transfer and chemical modeling, revealing mostly constant abundances in dense, UV-shielded areas and the influence of UV radiation in less shielded regions.

Contribution

It combines observational data with radiative transfer and chemical evolution models to analyze molecular abundances and gas densities in W40, providing insights into the impact of UV radiation on molecular chemistry.

Findings

01

HCN and HCO+ abundances are roughly constant in dense regions.

02

H2 densities are estimated between 5×10^4 and 5×10^5 cm^-3.

03

UV radiation affects molecular abundances in less shielded areas.

Abstract

We present observations of HCN and HCO $^{+}$ J = $3 - 2$ in the central $42 4^{''} \times 42 4^{''}$ region of the W40 massive star forming region. The observations were taken as part of a pilot project for the MAJORS large program at the JCMT telescope. By incorporating prior knowledge of N(H $_{2}$ ) and $T_{K}$ , assuming a constant density, and using the RADEX radiative transfer code we found that the HCN and HCO $^{+}$ abundances range from $X$ (HCN) = $0.4 - 7.0 \times 1 0^{- 8}$ and $X$ (HCO $^{+}$ ) = $0.4 - 7.3 \times 1 0^{- 9}$ . Additional modelling using the NAUTILUS chemical evolution code, that takes H $_{2}$ density variations into account, however, suggests the HCN and HCO $^{+}$ abundances may be fairly constant. Careful modelling of three different positions finds $X$ (HCN) = $1.3 - 1.7 \times 1 0^{- 8}$ , $X$ (HCO $^{+}$ ) = $1.3 - 3.1 \times 1 0^{- 9}$ . Cross-comparison of the two models also provides a crude estimate of…

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Taxonomy

TopicsAstrophysics and Star Formation Studies · Astronomy and Astrophysical Research · Stellar, planetary, and galactic studies