Neon is an inhibitor of CO hydrogenation in pre-stellar core conditions

TL;DR

Neon, traditionally considered inert, significantly inhibits CO hydrogenation in pre-stellar core conditions below 12 K, affecting the formation of formaldehyde and methanol on interstellar grains.

Contribution

This study reveals the inhibitory role of neon on CO hydrogenation in cold environments, a factor previously neglected in astrochemical models.

Findings

Ne significantly reduces H2CO formation at temperatures below 12 K.

Ne causes up to 91% decrease in H2CO production with multiple monolayers at 9 K.

Ne's presence also notably decreases CH3OH formation, though less than H2CO.

Abstract

Neon (Ne) is the fifth most abundant element in the Universe. Because it is chemically inert, it has never been considered in astrochemical models that studied molecular evolution. In the cold dark environments of pre-stellar cores, where the temperatures are below 10 K, Ne can condense onto the surface of interstellar grains. We investigated the effect of Ne on the production of formaldehyde (H$_2$CO) and methanol (CH$_3$OH) through carbon monoxide (CO) hydrogenation on different cold surfaces. We highlight its role in conditions corresponding to pre-stellar cores. In an ultra-high vacuum system, we conducted two types of experiments. The first experiment involved the co-deposition of CO and H atoms with or without Ne. The second experiment involved depositing a monolayer of CO and separately a monolayer of Ne (or vice versa), followed by bombarding the layers with hydrogen atoms. Additionally, we used a gas-grain chemical code to simulate a pre-stellar core and determine where Ne can affect the chemistry. The presence of Ne on the surface significantly inhibits CO hydrogenation at temperatures below 12 K. In the co-deposition experiments, we observed a 38% decrease in the H$_2$CO production at 11 K when the quantity of Ne in the mixture was lower than a monolayer. At 10 K and with one monolayer in the mixture, the production decreased to 77%, and it reached 91% for a few monolayers of Ne in the mixture at 9 K. While the decrease in CH$_3$OH formation is still notable, it is less pronounced: 43% at 11 K, 61% at 10 K, and 77% at 9 K. Experiments with stacked layers revealed that the CO layer decay varies slightly when the Ne layer is positioned above or below it. This observation indicates that Ne and CO create a mixture in which Ne can diffuse and stabilize at the surface, which isolates CO molecules from the accreting H atoms.