Herschel Measurements of Molecular Oxygen in Orion

TL;DR

This study reports the detection of molecular oxygen in Orion using Herschel, revealing high O2 abundance likely due to warm dust grain processes or low-velocity shocks, with implications for molecular cloud chemistry.

Contribution

First detection of molecular oxygen in Orion with detailed analysis of its abundance and origin, highlighting the role of warm dust grains or shocks in O2 formation.

Findings

Detected three rotational transitions of O2 with Herschel.

O2 fractional abundance is 0.3 - 7.3×10^-6.

Possible origin of O2 linked to warm dust or low-velocity shocks.

Abstract

We report observations of three rotational transitions of molecular oxygen (O2) in emission from the H2 Peak 1 position of vibrationally excited molecular hydrogen in Orion. We observed the 487 GHz, 774 GHz, and 1121 GHz lines using HIFI on the Herschel Space Observatory, having velocities of 11 km s-1 to 12 km s-1 and widths of 3 km s-1. The beam-averaged column density is N(O2) = 6.5\times1016 cm-2, and assuming that the source has an equal beam filling factor for all transitions (beam widths 44, 28, and 19"), the relative line intensities imply a kinetic temperature between 65 K and 120 K. The fractional abundance of O2 relative to H2 is 0.3 - 7.3\times10-6. The unusual velocity suggests an association with a ~ 5" diameter source, denoted Peak A, the Western Clump, or MF4. The mass of this source is ~ 10 M\odot and the dust temperature is \geq 150 K. Our preferred explanation of the enhanced O2 abundance is that dust grains in this region are sufficiently warm (T \geq 100 K) to desorb water ice and thus keep a significant fraction of elemental oxygen in the gas phase, with a significant fraction as O2. For this small source, the line ratios require a temperature \geq 180 K. The inferred O2 column density \simeq 5\times1018 cm-2 can be produced in Peak A, having N(H2) \simeq 4\times1024 cm-2. An alternative mechanism is a low-velocity (10 to 15 km s-1) C-shock, which can produce N(O2) up to 1017 cm-2.