During a close encounter of two members of the cluster, the members exchange both
energy and
momentum. Although energy can be exchanged in either direction, there is a statistical tendency for the
kinetic energy of the two members to equalize during an encounter; this statistical phenomenon is called
equipartition, and is similar to the fact that the expected kinetic energy of the molecules of a gas are all the same at a given temperature. Since kinetic energy is proportional to mass times the square of the speed, equipartition requires the less massive members of a cluster to be moving faster. The more massive members will thus tend to sink into lower orbits (that is, orbits closer to the center of the cluster), while the less massive members will tend to rise to higher orbits. The time it takes for the kinetic energies of the cluster members to roughly equalize is called the
relaxation time of the cluster. A relaxation time-scale assuming energy is exchanged through two-body interactions was approximated in the textbook by Binney & Tremaine as :t_\mathrm{relax}=\frac {N}{10\ln N}\times t_\mathrm{cross} \ , where N is the number of stars in the cluster and t_\mathrm{cross} is the typical time it takes for a star to cross the cluster. This is on the order of 100 million years for a typical
globular cluster with radius 10
parsecs consisting of 100 thousand stars. The most massive stars in a cluster can segregate more rapidly than the less massive stars. This time-scale can be approximated using a toy model developed by
Lyman Spitzer of a cluster where stars only have two possible masses (m_1 and m_2). In this case, the more massive stars (mass m_1) will segregate in the time :t_\mathrm{m_1}=\frac {m_2}{m_1}\times t_\mathrm{relax} \ . Outward segregation of
white dwarfs was observed in the globular cluster
47 Tucanae in a
HST study of the region. == Primordial mass segregation ==