Filamentary mass accretion towards the high-mass protobinary system G11.92-0.61 MM2

TL;DR

This study uses high-resolution ALMA observations to reveal filamentary gas accretion feeding a high-mass protobinary system, providing insights into mass inflow rates and ongoing star formation processes.

Contribution

It presents detailed kinematic analysis of filamentary accretion flows onto a high-mass protobinary, demonstrating ongoing mass transfer and estimating accretion rates with novel hierarchical clustering methods.

Findings

Filamentary structure traced by continuum and N$_2$H$^+$ emission.

Identification of 70 velocity-coherent clusters in the gas.

Estimated mass inflow rate of $ ext{~}1.8 imes10^{-4}$ to $1.2 imes10^{-3}$ M$_igodot$ yr$^{-1}$.

Abstract

We present deep, sub-arcsecond ($\sim$2000 AU) resolution ALMA 0.82 mm observations of the former high-mass prestellar core candidate G11.92-0.61 MM2, recently shown to be an $\sim$500 AU-separation protobinary. Our observations show that G11.92-0.61 MM2, located in the G11.92-0.61 protocluster, lies on a filamentary structure traced by 0.82 mm continuum and N$_2$H$^+$(4-3) emission. The N$_2$H$^+$(4-3) spectra are multi-peaked, indicative of multiple velocity components along the line of sight. To analyse the gas kinematics, we performed pixel-by-pixel Gaussian decomposition of the N$_2$H$^+$ spectra using SCOUSEPY and hierarchical clustering of the extracted velocity components using ACORNS. Seventy velocity- and position-coherent clusters (called "trees") are identified in the N$_2$H$^+$-emitting gas, with the 8 largest trees accounting for >60% of the fitted velocity components. The primary tree, with $\sim$20% of the fitted velocity components, displays a roughly north-south velocity gradient along the filamentary structure traced by the 0.82 mm continuum. Analysing a $\sim$0.17 pc-long substructure, we interpret its velocity gradient of $\sim$10.5 km s$^{-1}$pc$^{-1}$ as tracing filamentary accretion towards MM2 and estimate a mass inflow rate of $\sim$1.8$\times10^{-4}$ to 1.2$\times10^{-3}$ M$_\odot$ yr$^{-1}$. Based on the recent detection of a bipolar molecular outflow associated with MM2, accretion onto the protobinary is ongoing, likely fed by the larger-scale filamentary accretion flows. If 50% of the filamentary inflow reaches the protostars, each member of the protobinary would attain a mass of 8 M$_\odot$ within $\sim1.6\times$10$^5$ yr, comparable to the combined timescale of the 70 $\mu$m- and MIR-weak phases derived for ATLASGAL-TOP100 massive clumps using chemical clocks.