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Fading in the flow: suppression of cold gas growth in expanding galactic outflows

Multiphase outflows, revealed by multiwavelength observations, are crucial in redistributing gas and metals within and around galaxies. These outflows are often modelled theoretically using wind tunnel simulations of a cold ($\sim 10^4$ K) cloud interacting with a uniform hot ($\sim 10^6$ K) wind. H...

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Bibliographic Details
Main Authors: Dutta, Alankar (Author) , Sharma, Prateek (Author) , Grönke, Max (Author)
Format: Article (Journal)
Language:English
Published: December 2025
In: Monthly notices of the Royal Astronomical Society
Year: 2025, Volume: 544, Issue: 4, Pages: 4621-4650
ISSN:1365-2966
DOI:10.1093/mnras/staf1845
Online Access:Verlag, kostenfrei, Volltext: https://doi.org/10.1093/mnras/staf1845
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Author Notes:Alankar Dutta, Prateek Sharma and Max Gronke
Description
Summary:Multiphase outflows, revealed by multiwavelength observations, are crucial in redistributing gas and metals within and around galaxies. These outflows are often modelled theoretically using wind tunnel simulations of a cold ($\sim 10^4$ K) cloud interacting with a uniform hot ($\sim 10^6$ K) wind. However, real outflows expand downstream, a feature overlooked in most idealized simulations. We study how an expanding wind affects the survival, morphology, and dynamics of a cloud. We conduct idealized hydrodynamic simulations with optically thin radiative cooling of a cloud exposed to an expanding starburst-driven wind. This wind is specifically modelled as a steady, adiabatic outflow powered by constant mass and energy injection. We find that clouds remain locally isobaric with the wind, leading to a steep decline in their density contrast and eventual dissolution downstream. Compared to a plane-parallel wind, this suppresses cold gas mass growth because as clouds travel downstream, the surrounding mixed boundary layer becomes diffuse and less radiative. Our analytical scaling arguments show that cloud expansion and local pressure equilibrium are the key regulators of cold mass growth. Unlike traditional simulations, our model accounts for the differential expansion experienced by the long cometary tails of clouds in wind tunnels. This creates a strong head-to-tail emission gradient in the filamentary cold gas, which is more consistent with observations. We also demonstrate that the dynamics of individual clouds can substantially alter the radial properties of their host multiphase outflows.
Item Description:Veröffentlicht: 24. Oktober 2025
Gesehen am 26.02.2026
Physical Description:Online Resource
ISSN:1365-2966
DOI:10.1093/mnras/staf1845

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