On the chemistry and distribution of HOC+ in M82: More evidence for extensive PDRs

TL;DR

This study investigates the origin of reactive ions like HOC+ in M82, revealing their association with dense PDRs in the nuclear disk and providing insights into the galaxy's starburst evolution.

Contribution

The paper presents high-resolution interferometric mapping of HOC+ in M82 and refines chemical models to explain the distribution and abundance of reactive ions in starburst galaxy PDRs.

Findings

HOC+ emission is concentrated in dense PDRs within the nuclear disk.

Most molecular gas (~87%) is in small clouds, indicating an evolved starburst.

HOC+ and related ions are primarily produced in dense PDRs, not in intercloud regions.

Abstract

The molecular gas composition in the inner 1 kpc disk of the starburst galaxy M82 resembles that of Galactic Photon Dominated Regions (PDRs). In particular, large abundances of the reactive ions HOC+ and CO+ have been measured in the nucleus of this galaxy. To investigate the origin of the large abundances of reactive ions in M82, we have completed our previous 30m HOC+ J=1-0 observations with the higher excitation HCO+ and HOC+ J=4-3 and 3-2 rotational lines. In addition, we have obtained with the IRAM Plateau de Bure Interferometer (PdBI) a 4" resolution map of the HOC+ 1-0 emission, the first ever obtained in a Galactic or extragalactic source. Our HOC+ interferometric image shows that the emission of the HOC+ 1-0 line is mainly restricted to the nuclear disk, with the maxima towards the E. and W. molecular peaks. In addition, line excitation calculations imply that the HOC+ emission arises in dense gas. Therefore, the HOC+ emission is arising in the dense PDRs embedded in the M82 nuclear disk, rather than in the intercloud phase and/or wind. We have improved our previous chemical model of M82 by (i) using the new version of the Meudon PDR code, (ii) updating the chemical network, and (iii) considering two different types of clouds (with different thickness). Most molecular observations (HCO+, HOC+, CO+, CN, HCN, H3O+) are well explained assuming that ~ 87 % of the mass of the molecular gas is forming small clouds (Av=5 mag) while only ~ 13 % of the mass is in large molecular clouds (Av=50 mag). Such small number of large molecular clouds suggests that M82 is an old starburst, where star formation has almost exhausted the molecular gas reservoir.