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White Dwarfs

Published online by Cambridge University Press:  12 April 2016

Peter Thejll
Peter Thejll*
Affiliation:
Niels Bohr Institute, Blegdamsvej 17, DK-2100 Copenhagen, Denmark

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It is the intention of this review to explain what white dwarfs are and why it is interesting to study them, and why the H+2 molecule is of special interest.

The evolution, from start to finish, of a star of mass less than about 2 solar masses (M), can roughly be summarized as follows:

  1. A cloud of gas contracts from the interstellar medium until hydrogen ignites at the center and a main sequence (MS) star forms. H is transformed to He and the MS phase continues until H is exhausted in the stellar core.

  2. H continues burning in a shell outside the He core while the core contracts. He “ashes” are added to the core, and a red giant star is formed as the envelope expands. The star evolves up the Red Giant Branch (RGB) (i.e. it becomes more and more luminous and the surface cools).

  3. Towards the end of the RGB phase, mass-loss from the upper layers increases until helium to carbon burning in the core ignites suddenly under degenerate conditions – this is called the Helium Flash (HF). The HF terminates the RGB evolution, and therefore also the mass-loss and the growth of the stellar core.

  4. The star readjusts its structure and the He-core burns steadily on the horizontal branch (HB) (a phase of nearly-constant luminosity) until fuel is exhausted in the He-core.

  5. Then the C/O core contracts anew and the expansion of the envelope, and the growth of the core, during He-shell burning, mimics RGB evolution but relatively little mass is added to the core this time.

  6. The second ascent of the giant branch (the so-called Asymptotic Giant Branch, or AGB) continues with increased mass loss towards the end

  7. Rapid detachment of a considerable fraction of the remaining envelope and the hot core takes place, sometimes observable as the Planetary Nebulae (PN) phase.

  8. The PN is dispersed as the core contracts to a white dwarf (WD).

  9. The WD cools for a long time, as internal kinetic energy and latent heat is released.

Type
Research Article
Information
International Astronomical Union Colloquium , Volume 146: Molecules in the Stellar Environment , 1994 , pp. 71 - 78
Copyright
Copyright © Springer-Verlag 1994

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