From AAS NOVA: “Making Realistic Nebulae from Fractal Gas” 

AASNOVA

From AAS NOVA

5 August 2022
Kerry Hensley

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The young stars at the center of the Rosette Nebula, pictured here, provide the energy that makes the nebula glow with red light. [John Corban & The European Space Agency [La Agencia Espacial Europea] [Agence spatiale européenne][Europäische Weltraumorganisation](EU)/The European Southern Observatory [La Observatorio Europeo Austral] [Observatoire européen austral][Europäische Südsternwarte](EU)(CL)/The National Aeronautics and Space Agency Photoshop FITS Liberator]

Researchers have modeled the turbulent gas of the interstellar medium in a new way, with important implications for how we interpret observations of distant galaxies.

Probing the Early Universe

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The nebulae surrounding young stars, like the S106 star-forming region pictured here, frequently show intricate and irregular structure. [NASA & ESA]

How can we tell what makes galaxies billions of light-years away shine? Astronomers use photoionization models to analyze the photons we collect from galaxies in the early universe and discern what sources of energy, like young stars, shocks, or active galactic nuclei, make them glow.

In a recent study, a team led by Yifei Jin (金刈非; Australian National University and ARC Centre of Excellence for All Sky Astrophysics in 3 Dimensions) used photoionization models — with a turbulent twist — to simulate the intricate emission nebulae that surround young, massive stars in galaxies near and far.

Forming Fractal Gas

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Top: The modeled H-beta emission from the nebula. Bottom: The density of the interstellar gas with the outline of the nebula traced on top. [Jin et al. 2022]

Jin and collaborators used state-of-the-art models to simulate realistic emission nebulae from turbulent interstellar gas. The team placed a synthetic O star a million times more luminous than the Sun at the center of a cube 140 light-years on each side. They filled the cube with gas with an average density of 100 particles per cubic centimeter — a typical value for nebulae in the Milky Way — and the same chemical composition as the Sun.

The main advance in this work is the use of a fractal density pattern for the simulated interstellar gas. Unlike previous models, which assumed that the gas had the same density throughout, the team’s model incorporates density variations on large and small scales, resulting in a clumpy interstellar medium similar to what is seen in observations. As high-energy photons from the synthetic O star ionize the gas, they create an emission nebula with a complex and irregular shape.

Volume versus Boundary

To determine the properties of their modeled nebula, Jin and collaborators tracked the strength of the emission lines and categorized each emission line as either a volume species or a boundary species, depending on where in the nebula the line was produced. The volume species — H-alpha, H-beta, and [O III] — are produced mainly in the body of the nebula, while the boundary species — [O I], [S II], and [N II] — are produced along the outer edge.

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Comparison of the fluxes of several emission lines and emission-line ratios between the realistic nebula case and the spherical nebula case. A value of zero indicates no change in flux or the flux ratio. [Jin et al. 2022]

By comparing against a modeled spherical nebula formed in a region of uniform gas, the team found that the more complex the structure of the nebula, the more prominent the emission from the boundary species. This effect becomes more important the more concentrated an emission line is toward the edge of the nebula; for instance, H-alpha emission is scarcely different between the two models, but [O I] emission — 99.5% of which is produced along the boundary of the nebula — soars by 253% when a realistic nebular shape is adopted.

This study by Jin and collaborators demonstrates that modeling turbulent interstellar gas in a realistic way can have a huge impact on the resultant emission lines — which in turn has implications for how we interpret emission lines from distant galaxies. The team predicts that using fractal geometry for models of interstellar gas will be key to interpreting observations of galaxies early in the universe, when interstellar gas was likely highly turbulent.

Citation

Theoretically Modeling Photoionized Regions with Fractal Geometry in Three Dimensions, Yifei Jin et al 2022 ApJL 934 L8
https://iopscience.iop.org/article/10.3847/2041-8213/ac80f3

See the full article here .


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AAS Mission and Vision Statement

The mission of the American Astronomical Society is to enhance and share humanity’s scientific understanding of the Universe.

The Society, through its publications, disseminates and archives the results of astronomical research. The Society also communicates and explains our understanding of the universe to the public.
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Adopted June 7, 2009

The society was founded in 1899 through the efforts of George Ellery Hale. The constitution of the group was written by Hale, George Comstock, Edward Morley, Simon Newcomb and Edward Charles Pickering. These men, plus four others, were the first Executive Council of the society; Newcomb was the first president. The initial membership was 114. The AAS name of the society was not finally decided until 1915, previously it was the “Astronomical and Astrophysical Society of America”. One proposed name that preceded this interim name was “American Astrophysical Society”.

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