Plummer model

The Plummer model or Plummer sphere is a density law that was first used by H. C. Plummer to fit observations of globular clusters.^[1] It is now often used as toy model in N-body simulations of stellar systems.

Description of the model

File:Plummer rho.png

The density law of a Plummer model

The Plummer 3-dimensional density profile is given by

\rho_P(r) = \bigg(\frac{3M}{4\pi a^3}\bigg)\bigg(1+\frac{r^2}{a^2}\bigg)^{-\frac{5}{2}}\,,

where M is the total mass of the cluster, and a is the Plummer radius, a scale parameter which sets the size of the cluster core. The corresponding potential is

\Phi_P(r) = -\frac{G M}{\sqrt{r^2+a^2}}\,,

where G is Newton's gravitational constant.

Properties

The mass enclosed within radius $r$ is given by

M(<r) = 4\pi\int_0^r r^2 \rho_P(r) dr = M{r^3\over\left(r^2+a^2\right)^{3/2}}

.

Many other properties of the Plummer model are described in Herwig Dejonghe's comprehensive paper.^[2]

Core radius $r_c$ , where the surface density drops to half its central value, is at $r_c =a\sqrt{\sqrt{2}-1}\approx0.64a$ .

Half-mass radius is $r_h \approx 1.3 a$

Virial radius is $r_V = \frac{16}{3 \pi} a \approx 1.7 a$

See also The Art of Computational Science^[3]

Applications

The Plummer model comes closest to representing the observed density profiles of star clusters, although the rapid falloff of the density at large radii ( $\rho\rightarrow r^{-5}$ ) is not a good description of these systems.

The behavior of the density near the center does not match observations of elliptical galaxies, which typically exhibit a diverging central density.

The ease with which the Plummer sphere can be realized as a Monte-Carlo model has made it a favorite choice of N-body experimenters, in spite of the model's lack of realism.^[4]

References

↑ Plummer, H. C. (1911), On the problem of distribution in globular star clusters, Mon. Not. R. Astron. Soc. 71, 460
↑ Dejonghe, H. (1987), A completely analytical family of anisotropic Plummer models. Mon. Not. R. Astron. Soc. 224, 13
↑ P.Hut and J.Makino. The Art of Computational Science
↑ Aarseth, S. J., Henon, M. and Wielen, R. (1974), A comparison of numerical methods for the study of star cluster dynamics. Astronomy and Astrophysics 37 183.

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[1] Plummer, H. C. (1911), On the problem of distribution in globular star clusters, Mon. Not. R. Astron. Soc. 71, 460

[2] Dejonghe, H. (1987), A completely analytical family of anisotropic Plummer models. Mon. Not. R. Astron. Soc. 224, 13

[3] P.Hut and J.Makino. The Art of Computational Science

[4] Aarseth, S. J., Henon, M. and Wielen, R. (1974), A comparison of numerical methods for the study of star cluster dynamics. Astronomy and Astrophysics 37 183.

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Plummer model

Contents

Description of the model

Properties

Applications

References

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