The possibility of determining the value of the Hubble constant using observations of galaxy clusters in X-ray and microwave wavelengths through the Sunyaev Zel’dovich (SZ) effect has long been known. Previous measurements have been plagued by relatively large errors in the observational data and severe biases induced, for example, by cluster triaxiality and clumpiness. The advent of Planck allows us to map the Compton parameter y , that is, the amplitude of the SZ effect, with unprecedented accuracy at intermediate cluster-centric radii, which in turn allows performing a detailed spatially resolved comparison with X-ray measurements. Given such higher quality observational data, we developed a Bayesian approach that combines informed priors on the physics of the intracluster medium obtained from hydrodynamical simulations of massive clusters with measurement uncertainties. We applied our method to a sample of 61 galaxy clusters with redshifts up to z ?< ?0.5 observed with Planck and XMM-Newton and find H _(0)?=?67?±?3 km s~(?1)Mpc~(?1).
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机译:人们早就知道有可能通过使用Sunyaev Zel’dovich(SZ)效应观察X射线和微波波长的星系团来确定哈勃常数的值。先前的测量受到观测数据中相对较大的误差和严重的偏差(例如,簇三轴性和结块性)的困扰。普朗克的问世使我们能够绘制康普顿参数y,即SZ效应的幅度,并在以簇中心为中心的中间半径上具有空前的准确性,从而可以与X射线测量结果进行详细的空间分辨比较。鉴于此类高质量的观测数据,我们开发了一种贝叶斯方法,该方法结合了从大型团簇的流体动力学模拟获得的具有测量不确定性的集群内介质的物理先验知识。我们将我们的方法应用于对61个星团进行采样的样本,这些星团在普朗克和XMM-牛顿观测到的红移高达z?<0.5,发现H _(0)?=?67?±?3 km s〜(?1)Mpc 〜(?1)。
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