Abstract

We present the results from the dynamical analysis of the cluster of galaxies RXJ0152.7-1357, which shows a complex structure in its X-ray emission, with two major clumps in the central region and a third clump in the Eastern region. Our analysis is based on redshift data for 187 galaxies. We find that RXJ0152.7-1357 appears as a well isolated peak in the redshift space at z = 0.836, which includes 95 galaxies recognized as cluster members. We compute the line-of-sight velocity dispersion of galaxies, sigma(V) = 1322(-68)(+74) km s(-1), which is significantly larger than what is expected in the case of a relaxed cluster with an observed X-ray temperature of 5-6 keV. We find evidence that this cluster is far from dynamical equilibrium, as shown by the non Gaussianity of the velocity distribution, the presence of a velocity gradient and a significant substructure. Our analysis shows that the high value of sV is due to the complex structure of RXJ0152.7-1357, i.e. to the presence of three galaxy clumps of different mean velocities. Using optical data we detect a low-velocity clump ( with sigma(V) = 300 - 500 km s(-1)) in the central southwest region and a high-velocity clump ( with sigma(V) similar to 700 km s(-1)) in the Eastern region, corresponding well to the South - West and East peaks detected in the X-ray emission. The central North - East X-ray peak is associated to the main galaxy structure with a velocity which is intermediate between those of the other two clumps and sigma(V) similar to 900 km s(-1). The mass of the whole system within 2 Mpc is estimated to lie in the range (1.2-2.2) x 10(15) M-., depending on the model adopted to describe the cluster dynamics. Such values are comparable to those of very massive clusters at lower redshifts. Analytic calculations based on the two-body model indicate that the system is most likely bound and currently undergoing merging. In particular, we suggest that the southwestern clump is not a small group, but rather the dense cluster-core of a massive cluster, most likely destined to survive tidal disruption during the merger.