Investigating the velocity structure and X-ray observable properties of simulated galaxy clusters with PHOX

Non-thermal motions in the intra-cluster medium (ICM) are believed to play a non-negligible role in the pressure support to the total gravitating mass of galaxy clusters. Future X-ray missions, such as ASTRO-H and ATHENA, will eventually allow us to directly detect the signature of these motions from high-resolution spectra of the ICM. In this paper, we present a study on a set of clusters extracted from a cosmological hydrodynamical simulation, devoted to explore the role of non-thermal velocity amplitude in characterising the cluster state and the relation between observed X-ray properties. In order to reach this goal, we apply the X-ray virtual telescope PHOX to generate synthetic observations of the simulated clusters with both Chandra and ATHENA, the latter used as an example for the performance of very high-resolution X-ray telescopes. From Chandra spectra we extract global properties, e.g. luminosity and temperature, and from ATHENA spectra we estimate the gas velocity dispersion along the line of sight from the broadening of heavy-ion emission lines (e.g. Fe). We further extend the analysis to the relation between non-thermal velocity dispersion of the gas and the L_X-T scaling law for the simulated clusters. Interestingly, we find a clear dependence of slope and scatter on the selection criterion for the clusters, based on the level of significance of non-thermal motions. Namely, the scatter in the relation is significantly reduced by the exclusion of the clusters, for which we estimate the highest turbulent velocities. Such velocity diagnostics appears therefore as a promising independent way to identify disturbed clusters, in addition to the commonly used morphological inspection.

[1]  R. Sunyaev,et al.  Width of X-ray lines as a diagnostic of gas motions in cooling flows , 2008 .

[2]  N. Grevesse,et al.  Abundances of the elements: Meteoritic and solar , 1989 .

[3]  T. Reiprich,et al.  The LX – Tvir relation in galaxy clusters: effects of radiative cooling and AGN heating , 2011, 1106.5185.

[4]  Turbulence in clusters of galaxies and X-ray line profiles , 2003, astro-ph/0310737.

[5]  W. Schmidt,et al.  Turbulence production and turbulent pressure support in the intergalactic medium , 2011, 1102.3352.

[6]  Germany,et al.  The structural and scaling properties of nearby galaxy clusters. II. The M-T relation , 2005, astro-ph/0502210.

[7]  M. Norman,et al.  Turbulent Motions and Shocks Waves in Galaxy Clusters simulated with AMR , 2009, 0905.3169.

[8]  R. Sunyaev,et al.  Resonant Scattering of X-ray Emission Lines in the Hot Intergalactic Medium , 2010, 1007.3263.

[9]  U. Cambridge,et al.  Constraints on turbulent velocity broadening for a sample of clusters, groups and elliptical galaxies using XMM–Newton , 2010, 1008.3500.

[10]  A. Finoguenov,et al.  Probing turbulence in the Coma galaxy cluster , 2004 .

[11]  Marcus Brüggen,et al.  Massive and refined - II. The statistical properties of turbulent motions in massive galaxy clusters with high spatial resolution , 2011 .

[12]  G. W. Pratt,et al.  Galaxy cluster X-ray luminosity scaling relations from a representative local sample (REXCESS) , 2008, 0809.3784.

[13]  V. Springel,et al.  Cosmological smoothed particle hydrodynamics simulations: a hybrid multiphase model for star formation , 2002, astro-ph/0206393.

[14]  A. Evrard,et al.  Detecting Intracluster Gas Motion in Galaxy Clusters: Mock Astro-E2 Observations , 2005, astro-ph/0503281.

[15]  R. Piffaretti,et al.  Total mass biases in X-ray galaxy clusters , 2008, 0808.1111.

[16]  On the detectability of turbulence and bulk flows in X-ray clusters , 2003, astro-ph/0310041.

[17]  F. Vazza,et al.  Turbulent gas motions in galaxy cluster simulations: the role of smoothed particle hydrodynamics viscosity , 2005 .

[18]  Edward J. Wollack,et al.  FIVE-YEAR WILKINSON MICROWAVE ANISOTROPY PROBE OBSERVATIONS: COSMOLOGICAL INTERPRETATION , 2008, 0803.0547.

[19]  Klaus Dolag,et al.  Observing simulated galaxy clusters with phox: a novel X‐ray photon simulator , 2011, 1112.0314.

[20]  L. Moscardini,et al.  Systematics in the X-ray cluster mass estimators , 2006, astro-ph/0602434.

[21]  D. Nagai,et al.  SHAPES OF GAS, GRAVITATIONAL POTENTIAL, AND DARK MATTER IN ΛCDM CLUSTERS , 2010, 1003.2270.

[22]  S. Borgani,et al.  Chemical enrichment of galaxy clusters from hydrodynamical simulations , 2007, 0705.1921.

[23]  M. Meneghetti,et al.  Lensing and x-ray mass estimates of clusters (simulations) , 2012, 1201.1569.

[24]  Cluster mergers and non‐thermal phenomena: a statistical magneto‐turbulent model , 2005 .

[25]  Duane A. Liedahl,et al.  New Calculations of Fe L-Shell X-Ray Spectra in High-Temperature Plasmas , 1995 .

[26]  J. Niemeyer,et al.  Hydrodynamical adaptive mesh refinement simulations of turbulent flows -II. Cosmological simulations of galaxy clusters , 2008, 0801.4729.

[27]  D. Liedahl,et al.  Collisional Plasma Models with APEC/APED: Emission-Line Diagnostics of Hydrogen-like and Helium-like Ions , 2001, astro-ph/0106478.

[28]  Matthew A. Bershady,et al.  Linear Regression for Astronomical Data with Measurement Errors and Intrinsic Scatter , 1996, astro-ph/9605002.

[29]  S. Borgani,et al.  Simulating the effect of active galactic nuclei feedback on the metal enrichment of galaxy clusters , 2009, 0909.0664.

[30]  K. Arnaud XSPEC: The First Ten Years , 1996 .

[31]  Dan McCammon,et al.  Interstellar photoelectric absorption cross-sections, 0.03-10 keV , 1983 .

[32]  K. Dolag,et al.  Velocity structure diagnostics of simulated galaxy clusters , 2010, 1012.1606.

[33]  H. Böhringer,et al.  The Mass Function of an X-Ray Flux-limited Sample of Galaxy Clusters , 1999, astro-ph/0111285.

[34]  K. Dolag,et al.  The Coma cluster magnetic field from Faraday rotation measures , 2009, 1002.0594.

[35]  Daisuke Nagai,et al.  RESIDUAL GAS MOTIONS IN THE INTRACLUSTER MEDIUM AND BIAS IN HYDROSTATIC MEASUREMENTS OF MASS PROFILES OF CLUSTERS , 2009, 0903.4895.

[36]  M. White,et al.  Hydrodynamic Simulations of the Sunyaev-Zeldovich Effect(s) , 2000, astro-ph/0008133.

[37]  V. Springel The Cosmological simulation code GADGET-2 , 2005, astro-ph/0505010.

[38]  T. D. Matteo,et al.  Modelling feedback from stars and black holes in galaxy mergers , 2004, astro-ph/0411108.

[39]  G. Bryan,et al.  Cluster Turbulence , 1998, astro-ph/9802335.

[40]  K. Mannheim,et al.  EVOLUTION OF SHOCKS AND TURBULENCE IN MAJOR CLUSTER MERGERS , 2010, 1001.1170.

[41]  T. Fang,et al.  ROTATION AND TURBULENCE OF THE HOT INTRACLUSTER MEDIUM IN GALAXY CLUSTERS , 2008, 0808.1106.

[42]  R. Valdarnini,et al.  The impact of numerical viscosity in SPH simulations of galaxy clusters , 2010, 1010.3378.

[43]  E. M. Churazov,et al.  Polarization of X-ray lines from galaxy clusters and elliptical galaxies - a way to measure the tangential component of gas velocity , 2009, 0912.0016.