5.2: The Ranges of Stellar Masses, Radii, and Luminosity

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Page ID: 141623

George W. Collins II
Ohio State University via Pachart Foundation

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In Section 2.2 b, we used the β* theorem to show that as the mass of a star increases, the ratio of radiation pressure to total pressure also increases so that by the time one reaches about 100M_⊙ approximately 80 percent of the pressure will be supplied by the photons themselves. Although it is not obvious, at about this mass the outer layers can no longer remain in stable equilibrium, and the star will begin to shed its mass. Very few stars with masses above 100M_⊙ are known to exist, and those that do show instabilities in their outer layers. At the other end of the mass scale, a mass of about 0.1M_⊙ is required to produce core temperatures and densities sufficient to provide a significant amount of energy from nuclear processes. Thus, we can take the range of stellar masses to span roughly 3 powers of 10 with the sun somewhat below the geometric mean.

If we include the white dwarfs, which may be the size of the earth or less, the range of observed stellar radii is about 6 powers of 10 with the sun again near the geometric mean. The observed range of stellar surface temperatures is by far the smallest being from about 2000 K for the coolest M star, to perhaps 50000 K for some O-type stars. If the temperature range is combined with the range in radii, it is clear that we could expect a range as great as 17 powers of 10 in the luminosity. In practice, the largest stars do not have the highest temperatures, so that the range in luminosity is nearer 10 powers of 10. A reasonable range of these parameters is then \[\begin{gathered}
10^{-1} M_{\odot} \leq M_* \leq 10^2 M_{\odot} \\
10^{-3} R_{\odot} \leq R_* \leq 10^3 R_{\odot} \\
10^{-4} L_{\odot} \leq L_* \leq 10^6 L_{\odot}
\end{gathered}\label{5.1.1}\]

This, then, represents the ranges of the defining parameters of those objects we call normal stars. The theory of stellar evolution will tell us which parameters are related to various aspects of a star's life.

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