JWST/NIRCam detections of dusty subsolar-mass young stellar objects in the Small Magellanic Cloud

June 2023 • 2023NatAs...7..694J

Authors • Jones, Olivia C. • Nally, Conor • Habel, Nolan • Lenkić, Laura • Fahrion, Katja • Hirschauer, Alec S. • Chu, Laurie E. U. • Meixner, Margaret • De Marchi, Guido • Nayak, Omnarayani • Robberto, Massimo • Sabbi, Elena • Zeidler, Peter • Alves de Oliveira, Catarina • Beck, Tracy • Biazzo, Katia • Brandl, Bernhard • Giardino, Giovanna • Jerabkova, Teresa • Keyes, Charles • Muzerolle, James • Panagia, Nino • Pontoppidan, Klaus • Rogers, Ciaran • Sargent, B. A. • Soderblom, David

Abstract • Low-mass stars are the most numerous stellar objects in the Universe. Before the James Webb Space Telescope (JWST), we had limited knowledge of how planetary systems around low-mass stars could form at subsolar metallicities. Here we present JWST observations of NGC 346, a star-forming region in the metal-poor Small Magellanic Cloud, revealing a substantial population of subsolar-mass young stellar objects (YSOs) with an infrared excess. We notice that continuing low-mass star formation is concentrated along dust filaments. We detected roughly 500 YSOs and pre-main-sequence (PMS) stars from more than 45,000 unique sources, using all four NIRCam wide filters with deep, high-resolution imaging. From these observations, we construct detailed near-infrared colour-magnitude diagrams with which preliminary categorizations of YSO classes are made. For the youngest, most deeply embedded objects, JWST/NIRCam is ten magnitudes more sensitive than Spitzer observations at comparable wavelengths, and reaches two magnitudes fainter than Hubble Space Telescope for more evolved PMS sources, corresponding to roughly 0.1 M. The infrared sensitivity and resolution of JWST allows us to detect embedded low-mass star formation in an extragalactic environment. Furthermore, evidence of infrared excesses and accretion suggests that the dust required for rocky planet formation is present at metallicities as low as 0.2 Z, which are akin to those in place at cosmic noon.


IPAC Authors

Laurie Chu

Postdoctoral Research Associate