List of most massive stars
From Wikipedia, the free encyclopedia
This is a list of the most massive stars. The list is ordered by solar mass.
Stellar mass is the most important attribute of a star. Combined with chemical compositions, mass determines a star’s luminosity, its physical size, and its ultimate fate.
| Star name | Solar Mass |
|---|---|
| Eta Carinae | 150 |
| Pistol Star | 150 |
| LBV 1806-20 | 130 |
| VV Cephei A | 100 |
| S Doradus | 100 |
| Pismis 24-1 | 100 |
| Cyg OB2-12 | 92 |
| WR 20ab | 80 |
| R 66 | 70 |
| R 126 | 30 |
[edit] Uncertainties and Caveats
The masses listed in the table are inferred from theory, using difficult measurements of the stars’ temperatures and absolute brightnesses. All the listed masses are uncertain: both the theory and the measurements are pushing their limits; either could be a bit off. However, the mass of WR20ab was obtained almost directly: when the stars are in binary systems (two stars moving around each other), it is possible to measure their masses just studying their orbital motion (Kepler laws). Then, in this list the only reliable mass is that of WR20ab.
Massive stars are rare. All the listed stars are many thousands of light years away, and that alone would make measurements difficult. In addition to being far away, it seems that most stars of such extreme mass are surrounded by clouds of outflowing gas. The surrounding gas gets in the way of the already difficult measurements of the stars’ temperatures and brightness, and greatly complicates the already messy issue of measuring their internal chemical composition. Hence these masses are contested, and being a subject of current research, are constantly being revised.
[edit] Eddington’s Size Limit
Astronomers have long theorized that as a protostar grows, that if it exceeds 120 Solar masses, something drastic must happen. Although the limit can be stretched for very early Population III stars, if any stars existed above 120 solar mass, they would challenge current theories of stellar evolution.
The limit on mass arises because stars of greater mass have a higher rate of core energy generation, which is higher far out of proportion to their greater mass. For a sufficiently massive star, the outward pressure of radiant energy generated by Nuclear fusion in the star’s core exceeds the inward pull of its own gravity. This is called the Eddington limit. Beyond this limit, a star ought to push itself apart, or at least shed enough mass to reduce its internal energy generation to a lower, maintainable rate. In theory, a more massive star could not hold itself together, because of the mass loss resulting from the outflow of stellar material.
Studying the Arches cluster, which is the densest known cluster of stars in our galaxy, astronomers have confirmed that stars in that cluster do not occur any larger than about 150 solar masses, or 150 times the mass of our Sun.
[edit] Other objects
- Regular black holes are objects with approx. 4–15 times the mass of our Sun.
- Intermediate-mass black holes range from 100-10,000 times the mass of our Sun.
- supermassive black holes are in the range of millions solar masses.
