Book contents
- Frontmatter
- Contents
- Preface
- Notation
- Part I Special Relativity
- Part II Riemannian geometry
- Part III Foundations of Einstein's theory of gravitation
- Part IV Linearized theory of gravitation, far fields and gravitational waves
- Part V Invariant characterization of exact solutions
- Part VI Gravitational collapse and black holes
- 35 The Schwarzschild singularity
- 36 Gravitational collapse – the possible life history of a spherically symmetric star
- 37 Rotating black holes
- 38 Black holes are not black – Relativity Theory and Quantum Theory
- 39 The conformal structure of infinity
- Part VII Cosmology
- Bibliography
- Index
36 - Gravitational collapse – the possible life history of a spherically symmetric star
Published online by Cambridge University Press: 05 May 2010
- Frontmatter
- Contents
- Preface
- Notation
- Part I Special Relativity
- Part II Riemannian geometry
- Part III Foundations of Einstein's theory of gravitation
- Part IV Linearized theory of gravitation, far fields and gravitational waves
- Part V Invariant characterization of exact solutions
- Part VI Gravitational collapse and black holes
- 35 The Schwarzschild singularity
- 36 Gravitational collapse – the possible life history of a spherically symmetric star
- 37 Rotating black holes
- 38 Black holes are not black – Relativity Theory and Quantum Theory
- 39 The conformal structure of infinity
- Part VII Cosmology
- Bibliography
- Index
Summary
The evolutionary phases of a spherically symmetric star
In our universe a star whose temperature lies above that of its surroundings continuously loses energy, and hence mass, mainly in the form of radiation, but also in explosive outbursts of matter. Here we want to sketch roughly the evolution of such a star which is essentially characterized and determined by the star's innate properties (initial mass and density, …) and its behaviour in the critical catastrophic phases of its life.
According to observation, stars exist for a very long time after they have formed from hydrogen and dust. Therefore they can almost always settle down to a relatively stable state in the interplay between attractive gravitational force, repulsive (temperature-dependent) pressure and outgoing radiation.
The first stable state is reached when the gravitational attraction has compressed and heated the stellar matter to such a degree that the conversion of hydrogen into helium is a long-term source of energy sufficient to prevent the star cooling and to maintain the pressure (a sufficiently large thermal velocity of the stellar matter) necessary to compensate thegravitational force. The average density of such a star is of the order of magnitude 1 g cm-3. A typical example of such a star is our Sun.
When the hydrogen of the star is used up, the star can switch over to other nuclear processes (possibly only after an unstable phase associated with explosions) and produce nuclei of higher atomic number. These processes will last a shorter time and follow one another more quickly.
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- Information
- RelativityAn Introduction to Special and General Relativity, pp. 310 - 321Publisher: Cambridge University PressPrint publication year: 2004