TY - JOUR
T1 - Turbulence in the intracluster medium
T2 - Simulations, observables, and thermodynamics
AU - Mohapatra, Rajsekhar
AU - Sharma, Prateek
N1 - Publisher Copyright:
© 2019 The Author(s) Published by Oxford University Press on behalf of the Royal Astronomical Society.
PY - 2019/4/21
Y1 - 2019/4/21
N2 - We conduct two kinds of homogeneous isotropic turbulence simulations relevant for the intracluster medium (ICM): (i) pure turbulence runs without radiative cooling and (ii) turbulent heating + radiative cooling runs with global thermal balance. For pure turbulence runs in the subsonic regime, the rms density and surface brightness (SB) fluctuations vary as the square of the rms Mach number (mathcal M-textrms). However, with thermal balance, the density and SB fluctuations (SB/SB) are much larger. These scalings have implications for translating SB fluctuations into a turbulent velocity, particularly for cool cores. For thermal balance runs with large (cluster core) scale driving, both the hot and cold phases of the gas are supersonic. For small-scale (one order of magnitude smaller than the cluster core) driving, multiphase gas forms on a much longer time-scale but mathcal M-textrms is smaller. Both small- and large-scale driving runs have velocities larger than the Hitomi results from the Perseus cluster. Thus, turbulent heating as the dominant heating source in cool cluster cores is ruled out if multiphase gas is assumed to condense out from the ICM. Next we perform thermal balance runs in which we partition the input energy into thermal and turbulent parts and tune their relative magnitudes. The contribution of turbulent heating has to be lesssim 10 rm per cent in order for turbulence velocities to match Hitomi observations. If the dominant source of multiphase gas is not cooling from the ICM (but say uplift from the central galaxy), the importance of turbulent heating cannot be excluded.
AB - We conduct two kinds of homogeneous isotropic turbulence simulations relevant for the intracluster medium (ICM): (i) pure turbulence runs without radiative cooling and (ii) turbulent heating + radiative cooling runs with global thermal balance. For pure turbulence runs in the subsonic regime, the rms density and surface brightness (SB) fluctuations vary as the square of the rms Mach number (mathcal M-textrms). However, with thermal balance, the density and SB fluctuations (SB/SB) are much larger. These scalings have implications for translating SB fluctuations into a turbulent velocity, particularly for cool cores. For thermal balance runs with large (cluster core) scale driving, both the hot and cold phases of the gas are supersonic. For small-scale (one order of magnitude smaller than the cluster core) driving, multiphase gas forms on a much longer time-scale but mathcal M-textrms is smaller. Both small- and large-scale driving runs have velocities larger than the Hitomi results from the Perseus cluster. Thus, turbulent heating as the dominant heating source in cool cluster cores is ruled out if multiphase gas is assumed to condense out from the ICM. Next we perform thermal balance runs in which we partition the input energy into thermal and turbulent parts and tune their relative magnitudes. The contribution of turbulent heating has to be lesssim 10 rm per cent in order for turbulence velocities to match Hitomi observations. If the dominant source of multiphase gas is not cooling from the ICM (but say uplift from the central galaxy), the importance of turbulent heating cannot be excluded.
KW - galaxies: clusters: intracluster medium
KW - hydrodynamics
KW - methods: numerical
KW - turbulence
UR - http://www.scopus.com/inward/record.url?scp=85062263509&partnerID=8YFLogxK
U2 - 10.1093/mnras/stz328
DO - 10.1093/mnras/stz328
M3 - Article
SN - 0035-8711
VL - 484
SP - 4881
EP - 4896
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 4
ER -