The effect of saturated thermal conduction on clouds in a hot plasma

Autor(en)
Bastian Sander, Gerhard Hensler
Abstrakt

We numerically investigate the internal evolution of multiphase clouds, which are at rest with respect to an ambient, highly ionized medium (HIM) representing the hot component of the circumgalactic medium. Time-dependent saturated thermal conduction and its implications like condensation rates and mixing efficiency are assessed in multiphase clouds. Our simulations are carried out by using the adaptive mesh refinement code Flash.. The model clouds are initially in both hydrostatic and thermal equilibrium and are in pressure balance with the HIM. Thus, they have steep gradients in both temperature and density at the interface to HIM leading to non-negligible thermal conduction. Several physical processes are considered numerically or semi-analytically: thermal conduction, radiative cooling and external heating of gas, self-gravity, mass diffusion, and dissociation of molecules and ionization of atoms. It turns out that saturated thermal conduction triggers a continuous condensation irrespective of cloud mass. Dynamical interactions with ambient HIM all relate to the radial density gradient in the clouds: (1) mass flux due to condensation is the higher the more homogeneous the clouds are; (2) mixing of condensed gas with cloud gas is easier in low-mass clouds, because of their shallower radial density gradient; and thus (3) accreted gas is distributed more efficiently. A distinct and sub-structured transition zone forms at the interface between cloud and HIM, which starts at smaller radii and is much narrower as deduced from analytical theory.

Organisation(en)
Institut für Astrophysik
Externe Organisation(en)
Hochschule Anhalt
Journal
Monthly Notices of the Royal Astronomical Society
Band
519
Seiten
1313-1326
Anzahl der Seiten
14
ISSN
0035-8711
DOI
https://doi.org/10.1093/mnras/stac3508
Publikationsdatum
02-2023
Peer-reviewed
Ja
ÖFOS 2012
103004 Astrophysik, 103043 Computational Physics
Schlagwörter
ASJC Scopus Sachgebiete
Astronomy and Astrophysics, Space and Planetary Science
Link zum Portal
https://ucrisportal.univie.ac.at/de/publications/4c092b85-bace-4695-b12d-103fd4354017