Young star’s supersonic outflow captured by Webb

Young star’s supersonic outflow captured by Webb

NASA’s⁤ James Webb Space ⁢Telescope has captured a high-resolution ⁢look at Herbig-Haro 211 (HH 211), a bipolar jet traveling through interstellar space ⁤at supersonic speeds. At roughly 1,000 light-years away from ⁤Earth in the constellation Perseus, the object is one of the youngest and nearest protostellar⁤ outflows,⁣ making it⁣ an‌ ideal target for Webb.

Herbig-Haro​ (HH) objects are luminous regions surrounding newborn stars, formed when stellar ‍winds or jets ​of gas spewing from these newborn stars form shock waves colliding⁢ with nearby gas and dust ⁣at high speeds. This image of HH 211 from NASA’s James Webb Space Telescope reveals an outflow ‌from ​a Class 0 protostar,⁣ an infantile analog of our sun when it ‍was ‌no ⁤more than a few tens of thousands ⁣of years ​old and with⁤ a mass only ‍8% of the present-day ⁤sun. (It will eventually​ grow into a star like the sun.)

Infrared imaging is powerful in studying newborn stars and their outflows, ‍because such stars are ⁣invariably still embedded within the ​gas ​from the molecular ⁣cloud in which ⁣they formed. The ​infrared emission of the​ star’s ⁣outflows penetrates the obscuring gas and⁢ dust, making a Herbig-Haro object like HH 211 ideal​ for observation with Webb’s sensitive infrared instruments. ‌Molecules excited ⁢by the ‍turbulent conditions, including molecular⁤ hydrogen, carbon monoxide, and ‌silicon monoxide, emit‌ infrared light that Webb can collect to map​ out the structure of the outflows.

The image showcases a series of bow shocks⁤ to the southeast (lower-left) and northwest (upper-right) as well as the ‌narrow bipolar jet that powers them. Webb reveals this scene⁣ in‌ unprecedented detail—roughly 5​ to⁢ 10 times higher spatial resolution⁣ than any previous images of HH 211. The ⁢inner jet is seen to “wiggle” with ‍mirror symmetry on either​ side of the ‍central protostar. This is in agreement with observations on smaller scales and ‍suggests that the protostar may in fact be an unresolved binary star.

Earlier observations⁣ of​ HH 211 with ​ground-based telescopes revealed giant bow ‍shocks moving away from us⁢ (northwest) and moving towards us ‍(southeast) and​ cavity-like structures ⁢in shocked‍ hydrogen and carbon monoxide respectively, as well ⁣as a ⁤knotty and ⁣wiggling bipolar jet in silicon monoxide. Researchers have‌ used Webb’s new observations to⁢ determine that the ⁤object’s outflow is relatively slow in​ comparison to more evolved protostars with similar​ types of outflows.

2023-09-15 01:48:02
Post from phys.org rnrn

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