EUROPEAN SPACE AGENCY

JWST/MIRI Detection of Suprathermal OH Rotational Emissions: Probing the Dissociation of the Water by Lyα Photons near the Protostar HOPS 370

DOI: 10.3847/2041-8213/ad3d48 Bibcode: 2024ApJ...966L..22N

Manoj, P.; Narang, Mayank; Beuther, Henrik; Gutermuth, Robert A.; Caratti o Garatti, Alessio; Fischer, William J.; Rubinstein, Adam E.; Evans, Neal J.; Tyagi, Himanshu; Nazari, Pooneh; Federman, Samuel; Watson, Dan M.; Megeath, S. Thomas; Klaassen, Pamela; Looney, Leslie W.; Stanke, Thomas; Tobin, John J.; Yang, Yao-Lun; Neufeld, David A.; Green, Joel; Tychoniec, Łukasz; Osorio, Mayra; Anglada, Guillem; Wolk, Scott; Van Dishoeck, Ewine F.

United States, India, Taiwan, Netherlands, Germany, Japan, Spain, Italy, United Kingdom

Abstract

Using the MIRI medium-resolution spectrometer on JWST, we have detected pure rotational, suprathermal OH emissions from the vicinity of the intermediate-mass protostar HOPS 370 (OMC2/FIR3). These emissions are observed from shocked knots in a jet/outflow and originate in states of rotational quantum number as high as 46 that possess excitation energies as large as E U /k = 4.65 × 104 K. The relative strengths of the observed OH lines provide a powerful diagnostic of the ultraviolet radiation field in a heavily extinguished region (A V ∼ 10–20) where direct UV observations are impossible. To high precision, the OH line strengths are consistent with a picture in which the suprathermal OH states are populated following the photodissociation of water in its $\tilde{B}-X$ band by ultraviolet radiation produced by fast (∼80 km s‑1) shocks along the jet. The observed dominance of emission from symmetric ( $A^{\prime} $ ) OH states over that from antisymmetric (A″) states provides a distinctive signature of this particular population mechanism. Moreover, the variation of intensity with rotational quantum number suggests specifically that Lyα radiation is responsible for the photodissociation of water, an alternative model with photodissociation by a 104 K blackbody being disfavored at a high level of significance. Using measurements of the Brα flux to estimate the Lyα production rate, we find that ∼4% of the Lyα photons are absorbed by water. Combined with direct measurements of water emissions in the ν 2 = 1 ‑ 0 band, the OH observations promise to provide key constraints on future models for the diffusion of Lyα photons in the vicinity of a shock front.

2024 The Astrophysical Journal
JWST 8
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