Mass segregation (astronomy)

Many globular clusters, such as the 13-Gyr old cluster M30 (pictured), are mass segregated.

In astronomy, dynamical mass segregation is the process by which heavier members of a gravitationally bound system, such as a star cluster, tend to move toward the center, while lighter members tend to move farther away from the center.

Equipartition of kinetic energy

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 ^[1] as

${\displaystyle t_{\mathrm {relax} }={\frac {N}{8\ln N}}\times t_{\mathrm {cross} }\ ,}$

where ${\displaystyle N}$ is the number of stars in the cluster and ${\displaystyle t_{\mathrm {cross} }}$ 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 (${\displaystyle m_{1}}$ and ${\displaystyle m_{2}}$). In this case, the more massive stars (mass ${\displaystyle m_{1}}$) will segregate in the time

${\displaystyle t_{\mathrm {m_{1}} }={\frac {m_{2}}{m_{1}}}\times t_{\mathrm {relax} }\ .}$

Outward segregation of white dwarfs was observed in the globular cluster 47 Tucanae in a HST study of the region.^[2]

Primordial mass segregation

Mass segregation is occasionally seen in clusters in star-forming regions like W40 (pictured).^[3]

Primordial mass segregation is non-uniform distribution of masses present at the formation of a cluster. The argument that a star cluster is primordially mass segregated is typically based on a comparison of virialization timescales and the cluster's age. However, several dynamical mechanisms to accelerate virialization compared to two-body interactions have been examined.^[4] In star-forming regions, it is often observed that O-type stars are preferentially located in the center of a young cluster.

Evaporation

After relaxation, the speed of some low mass members can be greater than the escape velocity of the cluster, which results in these members being lost to the cluster. This process is called evaporation. (A similar phenomenon explains the loss of lighter gases from a planet, such as hydrogen and helium from the Earth—after equipartition, some molecules of sufficiently light gases at the top of the atmosphere will exceed the escape velocity of the planet and be lost.)

Through evaporation, most open clusters eventually dissipate, as indicated by the fact that most existing open clusters are quite young. Globular clusters, being more tightly bound, appear to be more durable.

In the Galaxy

The relaxation time of the Milky Way galaxy is approximately 10 trillion years, on the order of thousand times the age of the galaxy itself. Thus, any observed mass segregation in our galaxy must be almost entirely primordial.^{[citation needed]}

See also

• n-body problem – Problem in physics and celestial mechanics
• Virial theorem – Theorem of statistical mechanics
• Messier 67 – Old open cluster in the constellation Cancer
• Willman 1 – Ultra-low luminosity dwarf galaxy
• Orion Nebula Cluster – Open cluster in the Orion Nebula in the constellation Orion
• Westerhout 40 – Star-forming region in the constellation Serpens

References

1. Binney, James (2008). Galactic dynamics (2nd ed.). Princeton: Princeton University Press. ISBN 978-0-691-13026-2. OCLC 195749071.
2. "Hubble Catches Stellar Exodus in Action". Space Daily. 18 May 2015.
3. Kuhn, M. A.; et al. (2010). "A Chandra Observation of the Obscured Star-forming Complex W40". Astrophysical Journal. 725 (2): 2485–2506. arXiv:1010.5434. Bibcode:2010ApJ...725.2485K. doi:10.1088/0004-637X/725/2/2485. S2CID 119192761.
4. McMillan, S. L.; et al. (2007). "A Dynamical Origin for Early Mass Segregation in Young Star Clusters". Astrophysical Journal. 655 (1): L45–L49. arXiv:astro-ph/0609515. Bibcode:2007ApJ...655L..45M. doi:10.1086/511763.

Sources

• Ian A. Bonnell, Melvyn B. Davies (1998). "Mass segregation in young stellar clusters". Monthly Notices of the Royal Astronomical Society. 295 (3): 691–698. Bibcode:1998MNRAS.295..691B. doi:10.1046/j.1365-8711.1998.01372.x.

• Merritt, David (2013). Dynamics and Evolution of Galactic Nuclei. Princeton University Press. ISBN 978-0-691-12101-7. OCLC 820123438.

• Spitzer, Lyman S. (Jr) (1987). Dynamical Evolution of Globular Clusters. Princeton University Press. ISBN 0-691-08309-6.

• White, S. D. M. (April 1977). "Mass segregation and missing mass in the Coma cluster". Monthly Notices of the Royal Astronomical Society. 179 (2): 33–41. Bibcode:1977MNRAS.179...33W. doi:10.1093/mnras/179.2.33.