Improving Accretion Diagnostics for Young Stellar Objects with Mid-infrared Hydrogen lines from JWST/MIRI
Abstract
We present a comprehensive study of mid-infrared neutral hydrogen (H~i) emission lines in 79 nearby (d < 200 pc) young stars using JWST/MIRI. We aim to identify mid-infrared H~i transitions that can serve as reliable accretion diagnostics in young stars, and evaluate their utility in deriving physical conditions of the accreting gas. We identify and measure 22 H~i transitions in the MIRI wavelength regime (5-28 μ m) and perform LTE slab modelling to remove the H2O contribution from selected H~i transitions. We find that mid-IR H~i line emission is spatially compact, even for sources with spatially extended [Ne~ii] and [Fe~ii] jets, suggesting minimal contamination from extended jet. Although Pfund~α (H~i~6--5) and Humphreys~α (H~i~7--6) are the strongest lines, they are blended with H2O transitions. This blending necessitates additional processing to remove molecular contamination, thereby limiting their use as accretion diagnostics. Instead, we identify the H~i~(8--6) at 7.502 μ m and H~i~(10--7) at 8.760 μ m transitions as better alternatives, as they are largely unaffected by molecular contamination and offer a more reliable means of measuring accretion rates from MIRI spectra. We provide updated empirical relations for converting mid-IR H~i line luminosities into accretion luminosity for 6 different H~i lines in the MIRI wavelength range. Moreover, comparison of observed line ratios with theoretical models shows that MIR H~i lines offer robust constraints on the hydrogen gas density in accretion columns, nH = 1010.6 to 1011.2 cm-3 in most stars, with some stars exhibiting lower densities (<1010~cm-3), approaching the optically thin regime.
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