The chemistry of phosphorus-bearing molecules under energetic phenomena

TL;DR

This paper investigates the chemistry of phosphorus-bearing molecules in various energetic astrophysical environments, revealing how physical conditions influence their abundance ratios and proposing new formation pathways.

Contribution

It provides a comprehensive analysis of phosphorus chemistry across different environments and introduces a new gas-phase formation route for PO in shocks.

Findings

PO/PN ratio varies with environmental conditions

Proposed P + OH --> PO + H as a new formation pathway

Modeling aids in understanding P-bearing molecules in galactic and extragalactic sources

Abstract

For decades, the detection of phosphorus-bearing molecules in the interstellar medium was restricted to high-mass star-forming regions (as e.g. SgrB2 and Orion KL) and the circumstellar envelopes of evolved stars. However, recent higher-sensitivity observations have revealed that molecules such as PN and PO are present not only toward cold massive cores and low-mass star-forming regions with PO/PN ratios >1, but also toward the Giant Molecular Clouds in the Galactic Center known to be exposed to highly energetic phenomena such as intense UV radiation fields, shock waves and cosmic rays. In this paper, we carry out a comprehensive study of the chemistry of phosphorus-bearing molecules across different astrophysical environments which cover a range of physical conditions (cold molecular dark clouds, warm clouds, hot cores/hot corinos) and are exposed to different physical processes and energetic phenomena (proto-stellar heating, shock waves, intense UV radiation and cosmic rays). We show how the measured PO/PN ratio (either >1 as in e.g. hot molecular cores, or <1 as in UV strongly illuminated environments) can provide constraints on the physical conditions and energetic processing of the source. We propose that the reaction P + OH --> PO + H, not included in previous works, could be an efficient gas-phase PO formation route in shocks. Our modelling provides a template with which to study the detectability of P-bearing species not only in regions in our own Galaxy but also in extragalactic sources.