Cooling rate and turbulence in the intracluster medium of the cool-core cluster Abell 2667

Context. We present a detailed analysis of the thermal X-ray emission from the intracluster medium in the cool-core galaxy cluster Abell 2667 at z = 0.23. Aims. Our main goal is to detect low-temperature (< 2 keV) X-ray emitting gas associated with a potential cooling flow connecting the hot intracluster medium reservoir to the cold gas phase responsible for star formation and supermassive black hole feeding. Methods. We combined new deep XMM-Newton EPIC and RGS data, along with archival Chandra data, and performed a spectral analysis of the emission from the core region. Results. We find 1 sigma upper limits on the fraction of gas cooling equal to similar to 40 M-circle dot yr(-1) and similar to 50-60 M-circle dot yr(-1), in the temperature ranges of 0.5-1 keV and 1-2 keV, respectively. We do not identify OVII, FeXXI-FeXXII, and FeXVII recombination and resonant emission lines in our RGS spectra, implying that the fraction of gas cooling below 1 keV is limited to a few tens of solar masses per year at maximum. We do detect several lines (particularly SiXIV, MgXII, FeXXIII/FeXXIV, NeX, OVIII alpha) from which we are able to estimate the turbulent broadening. We obtain a 1 sigma upper limit of similar to 320 km/s, which is much higher than the one found in other cool-core clusters such as Abell 1835, suggesting the presence of some mechanisms that boost significant turbulence in the atmosphere of Abell 2667. Imaging analysis of Chandra data suggests the presence of a cold front possibly associated with sloshing or with intracluster medium cavities. However, current data do not allow us to clearly identify the dominant physical mechanism responsible for turbulence. Conclusions. These findings show that Abell 2667 is not different from other, low-redshift, cool-core clusters, with only upper limits on the mass deposition rate associated with possible isobaric cooling flows. Despite the lack of clear signatures of recent feedback events, the large upper limit on the turbulent velocity leaves room for significant heating of the intracluster medium, which may quench cooling in the cool core for an extended period, albeit also driving local intracluster medium fluctuations that will contribute to the next cycle of condensation rain.