Possible Counter Rotation between the Disk and Protostellar Envelope around the Class I Protostar IRAS 04169+2702

TL;DR

This study investigates the complex velocity structures around a Class I protostar, revealing potential counter-rotation between the disk and envelope, possibly influenced by magnetic fields during star formation.

Contribution

It presents high-resolution observations and modeling suggesting counter-rotation in the protostellar system, a phenomenon not clearly established in previous studies.

Findings

Opposite velocity gradients in different molecular lines.

Counter-rotating disk and envelope models fit observations better.

Estimated Keplerian radius of 200 au and stellar mass of 0.1 solar masses.

Abstract

We present results from our SMA observations and data analyses of the SMA archival data of the Class I protostar IRAS 04169+2702. The high-resolution (~0.5") $^{13}$CO (3-2) image cube shows a compact ($r$ ~< 100 au) structure with a northwest (blue) to southeast (red) velocity gradient, centered on the 0.9-mm dust-continuum emission. The direction of the velocity gradient is orthogonal to the axis of the molecular outflow as seen in the SMA $^{12}$CO (2-1) data. A similar gas component is seen in the SO (6$_5$-5$_4$) line. On the other hand, the C$^{18}$O (2-1) emission traces a more extended ($r$ ~400 au) component with the opposite, northwest (red) to southeast (blue) velocity gradient. Such opposite velocity gradients in the different molecular lines are also confirmed from direct fitting to the visibility data. We have constructed models of a forward-rotating and counter-rotating Keplerian disk and a protostellar envelope, including the SMA imaging simulations. The counter-rotating model could better reproduce the observed velocity channel maps, although we could not obtain statistically significant fitting results. The derived model parameters are; Keplerian radius of 200 au, central stellar mass of 0.1 $M_{solar}$, and envelope rotational and infalling velocities of 0.20 km s$^{-1}$ and 0.16 km s$^{-1}$, respectively. One possible interpretation for these results is the effect of the magnetic field in the process of disk formation around protostars, $i.e.$, Hall effect.