CORINOS. III. Outflow Shocked Regions of the Low-mass Protostellar Source IRAS 15398-3359 with JWST and ALMA
Abstract
While molecular outflows have been studied in details with radio interferometry, observations of the hotter gas in protostellar outflows at a comparable physical scale is often challenging. Combined with ALMA, JWST allows us to investigate the cold and hot gas with unprecedented spatial resolution and sensitivity. We present a detailed comparison between the gas distributions probed with ALMA and JWST in the primary outflow of IRAS 15398-3359. At 2000 au scale, the southwestern outflow shows four shell structures in 5--10 micron continuum, whereas the submillimeter H2CO emission traces two of the four shells closest to the protostar. Submillimeter emission from CS, CCH, c-C3H2, and CH3OH shows the same two shells, and the 12CO emission covers most of the outflow region. SO and SiO only trace a condensation at the edge of the shell closest to the protostar. None of these lines observed with ALMA show the outermost shell. At 500 au scale, we find hot H2 gas inside the outflow cavity with JWST. The derived temperature of H2 is 1147198 K within a 05 aperture at the protostar. The foreground mass column density of dust is (1.4--2.0)×10-3 g·cm-2 (A v = 47--66 mag) in the outflow, using the dust model from Weingartner & Draine (2001). We also find an 8 difference between the directions toward the [Fe II] knot and the outermost shell in the MIRI image, which may be interpreted as the precession of the [Fe II] jet. The dynamical timescale of the [Fe II] knot is 10 yrs, suggesting a current event.
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