The role of SiO as a tracer of past star-formation events: The case of the high-mass protocluster NGC 2264-C

TL;DR

This study investigates SiO as a tracer of past star-formation in the high-mass protocluster NGC 2264-C, revealing complex outflow activity and chemical signatures indicative of previous star-forming episodes.

Contribution

It provides the first detailed analysis of SiO distribution and abundance in NGC 2264-C, linking chemical signatures to past star-formation events and outflow activity.

Findings

SiO emission is strongest beyond 0.1 pc from the center.

Within the core, SiO is depleted due to condensation and destruction.

A peripheral narrow-line SiO component may trace past shocks or unresolved protostars.

Abstract

NGC 2264-C is a high-mass protocluster where several star-formation events are known to have occurred. To investigate whether past protostellar activity has left a chemical imprint in this region, we mapped it in SiO($J = 2-1$), a shock tracer, and several other molecular lines with the Nobeyama 45 m telescope. Our observations show the presence of a complex network of protostellar outflows. The strongest SiO emission lies beyond a radius of $\sim 0.1$ pc with respect to the center of the clump, and is characterized by broad ($> 10$ km s$^{-1}$) lines and abundances of $\sim 1.4 \times 10^{-8}$ with respect to H$_2$. Interestingly, SiO appears relatively depleted ($\chi_\mathrm{SiO} \sim 4 \times 10^{-9}$) within this radius, despite it being affected by molecular outflow activity. We attribute this to fast condensation of SiO back onto dust grains and/or rapid gas-phase destruction of SiO, favored by the high density present in this area ($> 10^6$ cm$^{-3}$). Finally, we identify a peripheral, narrow-line ($\sim 2$ km s$^{-1}$) component, where SiO has an abundance of a few times 10$^{-11}$. After considering different options, we conclude that this weak emission may be tracing protostellar shocks from the star formation episode that preceded the current one, which have decelerated over time and eventually resulted in SiO being largely depleted/destroyed. Alternatively, a population of unresolved low-mass protostars may be responsible for the narrow SiO emission. High-angular resolution observations are necessary to distinguish between these two possibilities and thus understand the role of SiO as a chemical tracer of past star-formation episodes in massive protoclusters.