JOYS+: A JWST/MIRI survey of the evolution of H2 winds and jets from low-mass protostars

Abstract

Protostellar outflows display wide-angle winds and collimated jets, the magnetocentrifugal launching of which enables accretion onto the protostar. The majority of the outflow mass is likely ejected or entrained molecular H2, which can now be studied in unprecedented detail with JWST. Using JWST MIRI/MRS observations towards 13 single and 20 multiple Class 0 and I protostars, we investigate the nature and evolution of the H2 wind and jet morphology, mass outflow rate, and velocity and temperature structure. We construct line flux and velocity maps of the H2 S(1) and S(7) lines as well as the sub-mm CO traced by ALMA. Low-J (J4) H2 transitions trace extended wide-angle, low-velocity (0-20 km s-1) winds within the contours of the low-velocity (< 30 km s-1) sub-mm CO emission, while high-J (J >5) transitions are associated with shocks and knots. In Class 0 sources with a known high-velocity (> 30 km s-1) molecular CO or SiO jet, higher H2 velocities are found along the jet axis. The opening angle of the wind traced by the H2 S(1) line broadens from 20 to 90 through the Class 0 to Class I stage. Near the base of each blue-shifted outflow lobe, we extract representative spectra, where rotation diagram fitting of the H2 lines is combined with the outflow width and H2 line velocity to measure the mass-loss rates. The rotation diagrams show a warm 600 K, component with two orders of magnitude more mass than the hot, 1500-3000 K component. The H2 outflow mass-loss rates decline by two orders of magnitude from the Class 0 to Class II stage and are correlated with bolometric luminosity. The declining warm H2 mass loss rates and increasing opening angles from the Class 0 to I stages, and the absence of H2 jets in the Class I sources, are consistent with the predictions of MHD disk wind models.