Astronomowie odkryli pierścienie o niemal idealnej symetrii w Mgławicy Kocie Oko
Naukowcy zbudowali pierwszy wygenerowany komputerowo model 3D mgławicy Kocie Oko, odsłaniając parę symetrycznych pierścieni wokół zewnętrznej powłoki mgławicy. Symetria pierścieni wskazuje, że zostały utworzone przez strumień dżetów pochodzący z centralnej gwiazdy mgławicy. To dostarcza mocnych dowodów na istnienie podwójnej gwiazdy w centrum mgławicy. Badanie zostało niedawno opublikowane w czasopiśmie Comiesięczne zawiadomienia Królewskiego Towarzystwa Astronomicznego Prowadził ją Ryan Claremont.
Mgławica planetarna powstaje, gdy umierająca gwiazda wyrzuca swoją zewnętrzną warstwę gazu, tworząc barwną, podobną do powłoki strukturę, charakterystyczną dla mgławic planetarnych. NGC 6543, czyli Mgławica Kocie Oko, jest jedną z najbardziej złożonych znanych mgławic planetarnych. Znajduje się nieco ponad 3000 lat świetlnych od Ziemi i można ją zobaczyć w konstelacji Draco. Mgławica Kocie Oko była również bardzo szczegółowo obserwowana przez[{” attribute=””>Hubble Space Telescope, exhibiting a complicated structure of knots, spherical shells, and arc-like filaments.
The nebula’s mysterious structure confounded astrophysicists because it could not be explained by previously accepted theories for planetary nebula formation. More recent research showed that precessing jets were potential shaping mechanisms in complex planetary nebulae such as NGC 6543, but lacked a detailed model.
Clairmont, an astronomy enthusiast, decided to try to establish the detailed 3D structure of the Cat’s Eye to find out more about the potential mechanism that gave it its intricate shape. To do this, he sought out the help of Dr. Wolfgang Steffen of The National Autonomous University of Mexico and Nico Koning from the University of Calgary, who developed SHAPE, 3D astrophysical modeling software particularly suitable for planetary nebulae.
The researchers used spectral data from the San Pedro Martir National Observatory in Mexico to reconstruct the nebula’s three-dimensional structure’s three-dimensional structure. These provide detailed information on the internal motion of material in the nebula. Together with these data and images from the Hubble Space Telescope, Clairmont constructed a novel 3D model, establishing that rings of high-density gas were wrapped around the outer shell of the Cat’s Eye. Surprisingly, the rings are almost perfectly symmetric to each other, suggesting they were formed by a jet – a stream of high-density gas ejected in opposite directions from the nebula’s central star.
The jet exhibited precession, similar to the wobbling motion of a spinning top. As the jet wobbled, or precessed, it outlined a circle, creating the rings around the Cat’s Eye. However, the data indicates the rings are only partial, meaning the precessing jet never completed a full 360-degree rotation, and that the emergence of the jets was only a short-lived phenomenon. The duration of outflows is an important piece of information for the theory of planetary nebulae. Since only binary stars can power a precessing jet in a planetary nebula, the team’s findings are strong evidence that a system of this type exists at the center of the Cat’s Eye.
As the angle and direction of the jet changed over time, it likely formed all of the features seen in the Cat’s Eye, including the jets and knots. Using the three-dimensional model, the researchers were able to calculate the tilt and opening angle of the precessing jet based on the orientation of the rings.
Ryan Clairmont, the lead author of the paper and now a prospective undergraduate at Stanford University stated, “When I first saw the Cat’s Eye Nebula, it was astonishing. It had a beautiful, perfectly symmetric structure. I was even more surprised that its 3D structure was not fully understood.”
He continued, “It was very rewarding to be able to do astrophysical research of my own that actually has an impact in the field. Precessing jets in planetary nebulae are relatively rare, so it’s important to understand how they contribute to the shaping of more complex systems like the Cat’s Eye. Ultimately, understanding how they form provides insight into the eventual fate of our Sun, which will itself one day become a planetary nebula.”
Reference: “Morphokinematic modelling of the point-symmetric Cat’s Eye, NGC 6543: Ring-like remnants of a precessing jet” by Ryan Clairmont, Wolfgang Steffen and Nico Koning, 15 September 2022, Monthly Notices of the Royal Astronomical Society.
DOI: 10.1093/mnras/stac2375
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