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A new method for spatially resolving the turbulence-driving mixture in the ISM with application to the Small Magellanic Cloud

Isabella A Gerrard, Christoph Federrath, Nickolas M. Pingel, N. M. McClure‐Griffiths, Antoine Marchal, Gilles Joncas, Susan E. Clark, Snežana Stanimirović, Min-Young Lee, Jacco Th. van Loon, J. M. Dickey, Helga Dénes, Yik Ki, James Dempsey, Callum Lynn

2023Monthly Notices of the Royal Astronomical Society20 citationsDOIOpen Access PDF

Abstract

ABSTRACT Turbulence plays a crucial role in shaping the structure of the interstellar medium. The ratio of the three-dimensional density contrast ($\sigma _{\rho /\rho _0}$) to the turbulent sonic Mach number ($\mathcal {M}$) of an isothermal, compressible gas describes the ratio of solenoidal to compressive modes in the turbulent acceleration field of the gas, and is parameterized by the turbulence driving parameter: $b=\sigma _{\rho /\rho _0}/\mathcal {M}$. The turbulence driving parameter ranges from b = 1/3 (purely solenoidal) to b = 1 (purely compressive), with b = 0.38 characterizing the natural mixture (1/3 compressive, 2/3 solenoidal) of the two driving modes. Here, we present a new method for recovering $\sigma _{\rho /\rho _0}$, $\mathcal {M}$, and b, from observations on galactic scales, using a roving kernel to produce maps of these quantities from column density and centroid velocity maps. We apply our method to high-resolution ${\rm H}\,\rm{\small I}$ emission observations of the Small Magellanic Cloud (SMC) from the GASKAP-HI survey. We find that the turbulence driving parameter varies between b ∼ 0.3 and 1.0 within the main body of the SMC, but the median value converges to b ∼ 0.51, suggesting that the turbulence is overall driven more compressively (b > 0.38). We observe no correlation between the b parameter and ${\rm H}\,\rm{\small I}$ or H α intensity, indicating that compressive driving of ${\rm H}\,\rm{\small I}$ turbulence cannot be determined solely by observing ${\rm H}\,\rm{\small I}$ or H α emission density, and that velocity information must also be considered. Further investigation is required to link our findings to potential driving mechanisms such as star-formation feedback, gravitational collapse, or cloud–cloud collisions.

Topics & Concepts

PhysicsSolenoidal vector fieldTurbulenceAstrophysicsVector fieldMechanicsAstrophysics and Star Formation StudiesStellar, planetary, and galactic studiesGalaxies: Formation, Evolution, Phenomena
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