WEIGHING GALAXY CLUSTERS WITH GAS. I. ON THE METHODS OF COMPUTING HYDROSTATIC MASS BIAS

Mass estimates of galaxy clusters from X-ray and Sunyeav-Zel'dovich observations assume the intracluster gas is in hydrostatic equilibrium with their gravitational potential. However, since galaxy clusters are dynamically active objects whose dynamical states can deviate significantly from the equilibrium configuration, the departure from the hydrostatic equilibrium assumption is one of the largest sources of systematic uncertainties in cluster cosmology. In the literature there have been two methods for computing the hydrostatic mass bias based on the Euler and the modified Jeans equations, respectively, and there has been some confusion about the validity of these two methods. The word 'Jeans' was a misnomer, which incorrectly implies that the gas is collisionless. To avoid further confusion, we instead refer these methods as 'summation' and 'averaging' methods respectively. In this work, we show that these two methods for computing the hydrostatic mass bias are equivalent by demonstrating that the equation used in the second method can be derived from taking spatial averages of the Euler equation. Specifically, we identify the correspondences of individual terms in these two methods mathematically and show that these correspondences are valid to within a few percent level using hydrodynamical simulations of galaxy cluster formation. In addition, we computemore » the mass bias associated with the acceleration of gas and show that its contribution is small in the virialized regions in the interior of galaxy clusters, but becomes non-negligible in the outskirts of massive galaxy clusters. We discuss future prospects of understanding and characterizing biases in the mass estimate of galaxy clusters using both hydrodynamical simulations and observations and their implications for cluster cosmology.« less

[1]  M. Meneghetti,et al.  Weighing simulated galaxy clusters using lensing and X-ray , 2009, 0912.1343.

[2]  D. Nagai,et al.  Testing X-Ray Measurements of Galaxy Clusters with Cosmological Simulations , 2006, astro-ph/0609247.

[3]  R. Sunyaev,et al.  Quantifying properties of ICM inhomogeneities , 2012, 1210.6706.

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

[5]  Yehuda Hoffman,et al.  Constrained Simulations of the Real Universe. II. Observational Signatures of Intergalactic Gas in the Local Supercluster Region , 2001, astro-ph/0109077.

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

[7]  D. Nagai,et al.  EVOLUTION OF THE MERGER-INDUCED HYDROSTATIC MASS BIAS IN GALAXY CLUSTERS , 2011, 1112.3659.

[8]  Samuel W. Skillman,et al.  GALAXY CLUSTERS AT THE EDGE: TEMPERATURE, ENTROPY, AND GAS DYNAMICS NEAR THE VIRIAL RADIUS , 2010, 1004.3553.

[9]  Resolving the Structure of Cold Dark Matter Halos , 2000, astro-ph/0006343.

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

[11]  A dynamical model for the distribution of dark matter and gas in galaxy clusters , 2003, astro-ph/0309405.

[12]  H. Hoekstra,et al.  JOINT ANALYSIS OF CLUSTER OBSERVATIONS. II. CHANDRA/XMM-NEWTON X-RAY AND WEAK LENSING SCALING RELATIONS FOR A SAMPLE OF 50 RICH CLUSTERS OF GALAXIES , 2012, 1210.3689.

[13]  A. Finoguenov,et al.  LoCuSS: A COMPARISON OF CLUSTER MASS MEASUREMENTS FROM XMM-NEWTON AND SUBARU—TESTING DEVIATION FROM HYDROSTATIC EQUILIBRIUM AND NON-THERMAL PRESSURE SUPPORT , 2010, 1001.0780.

[14]  T. Jeltema,et al.  Cluster Structure in Cosmological Simulations. I. Correlation to Observables, Mass Estimates, and Evolution , 2007, 0708.1518.

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

[16]  G. W. Pratt,et al.  XXIV. Cosmology from Sunyaev-Zeldovich cluster counts , 2015, 1502.01597.

[17]  Alexey Vikhlinin,et al.  CHANDRA CLUSTER COSMOLOGY PROJECT III: COSMOLOGICAL PARAMETER CONSTRAINTS , 2008, 0812.2720.

[18]  K. Getman,et al.  The soft X-ray light curves of partially eclipsed stellar flares , 2011, 1108.3999.

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

[20]  IoA,et al.  Improved constraints on dark energy from Chandra X-ray observations of the largest relaxed galaxy clusters , 2007, 0706.0033.

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

[22]  Validity of Hydrostatic Equilibrium in Galaxy Clusters from Cosmological Hydrodynamical Simulations , 2013, 1302.5172.

[23]  D. Nagai,et al.  WEIGHING GALAXY CLUSTERS WITH GAS. II. ON THE ORIGIN OF HYDROSTATIC MASS BIAS IN ΛCDM GALAXY CLUSTERS , 2013, 1308.6589.

[24]  Harvard,et al.  Effects of Galaxy Formation on Thermodynamics of the Intracluster Medium , 2007, astro-ph/0703661.

[25]  J. Lumley,et al.  A First Course in Turbulence , 1972 .

[26]  Douglas H. Rudd,et al.  The Astrophysical Journal, submitted Preprint typeset using L ATEX style emulateapj v. 08/29/06 EFFECTS OF BARYONS AND DISSIPATION ON THE MATTER POWER SPECTRUM , 2007 .