PROJECT-J: the shocking H2 outflow from HH46

TL;DR

This study uses JWST spectral data to analyze the physical conditions and origin of the warm molecular outflow in HH46, revealing shock interactions and expanding shells driven by binary sources, challenging some existing outflow models.

Contribution

It provides detailed physical parameters and kinematic analysis of HH46's outflow, demonstrating shock interactions as the primary excitation mechanism, and offers new insights into binary-driven outflow dynamics.

Findings

H2 emission arises from shock interactions with ambient medium

No temperature or velocity stratification observed in the outflow

H2 excitation consistent with low-velocity J-shocks irradiated by UV field

Abstract

We analyze the H2 emission observed in the HH46 Class I system as part of PROJECT-J (Protostellar Jets Cradle Tested with JWST), to investigate the origin and excitation of the warm molecular outflow. We used NIRSpec and MIRI spectral maps (1.6-27.9 microns) to trace the structure and physical conditions of the outflow. By fitting the H2 rotational diagrams with a multi-temperature gas model, we derived key physical parameters including temperature, extinction, column densities, and the ortho-to-para ratio. This information is combined with a detailed kinematical analysis and comparison with irradiated shock models. We find no evidence of H2 temperature or velocity stratification from the axis to the edge of the outflow, as would be expected in MHD disk-wind models and as observed in other outflows. Instead, the observations suggest that the H2 emission arises from shock interactions between jet bow shocks and/or wide-angle winds with the ambient medium and cavity walls. NIRSpec emission and velocity maps reveal expanding molecular shells, likely driven by the less luminous source in the binary system. We infer an accretion rate of less than 10^-9 solar masses per year for the secondary source, approximately one order of magnitude lower than that of the primary. The H2 emission is consistent with excitation by low-velocity (approximately 10 km/s) J-type shocks, irradiated by an external UV field that may originate from strong dissociative shocks driven by the atomic jet. Future JWST observations will further constrain the evolution of the expanding shell and the mechanisms driving the outflow.