white dwarf(redirected from White dwarf branch stars)
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white dwarf,in astronomy, a type of star that is abnormally faint for its white-hot temperature (see mass-luminosity relationmass-luminosity relation,
in astronomy, law stating that the luminosity of a star is proportional to some power of the mass of the star. More massive stars are in general more luminous.
..... Click the link for more information. ). Typically, a white dwarf star has the mass of the sun and the radius of the earth but does not emit enough light or other radiation to be easily detected. The existence of white dwarfs is intimately connected with stellar evolutionstellar evolution,
life history of a star, beginning with its condensation out of the interstellar gas (see interstellar matter) and ending, sometimes catastrophically, when the star has exhausted its nuclear fuel or can no longer adjust itself to a stable configuration.
..... Click the link for more information. . A white dwarf is the hot core of a star, left over after the star uses up its nuclear fuel and dies; the hottest known white dwarf has a temperature of 250,000°K;. Made mostly of carbon, a white dwarf is coated by a thin layer of hydrogen and helium gases. The physical conditions inside the star are quite unusual; the central density is about 1 million times that of water. Over time, white dwarfs gradually cool and no longer emit significant amounts of radiation.
Astronomers long believed this intense pressure could cause the carbon interiors of white dwarfs to crystallize. In 2004 the discovery of BPM-37093, a star that is located 50 light-years from the earth in the constellation Centaurus and is both pulsating and has sufficient mass to have a crystalline interior. By measuring the pulsations it was possible to study this white dwarf's interior and determine that it had crystallized to form an enormous diamond, some 950 mi (1,500 km) wide. Were it a diamond as we commonly know it, it would weigh some 10 billion trillion trillion carats.
The first white dwarf discovered (1844) was the faint companion in the binary star Sirius. Although invisible to the telescopes of the day, the white dwarf's mass was large enough to produce a noticeable wavy motion in its very bright partner as the two stars revolved around each other. It is believed that white dwarfs could represent as much as a third of the so-called dark matterdark matter,
material that is believed to make up nearly 27% of the mass of the universe but is not readily visible because it neither emits nor reflects electromagnetic radiation, such as light or radio signals.
..... Click the link for more information. in the universe.
white dwarfAn extremely dense compact star that has a mass below the Chandrasekhar limit (about 1.4 solar masses) and has undergone gravitational collapse. Having diameters only 1% that of the Sun these stars are consequently very faint, with absolute magnitudes ranging from +10 to +15. The description ‘white’ is misleading because they display a range in color as they cool down, through white, yellow, and red, until finally ending up as cold black globes – called black dwarfs. However, the white ones are the brightest and were the first to be discovered.
White dwarfs are the final phase in the evolution of a low-mass star. Their progenitors are stars of up to 8 solar masses, which lose up to 90% of their matter in the form of planetary nebulae. The core shrinks to become a white dwarf following the exhaustion of its nuclear fuel. Because most of the matter in the core of the collapsing star is in a degenerate state – with the electrons stripped from their nuclei and packed tightly together – the star contracts until its gravity is balanced by the degeneracy pressure of the electrons, and the density rises to 107–1011 kg m–3. Because of the peculiar behavior of degenerate material (which is subject to the quantum mechanical uncertainty principle), the most massive white dwarfs collapse to the smallest diameters and highest densities. Stars above the Chandrasekhar limit are too massive to be supported in this way and must collapse further to become neutron stars or black holes. In practice, the addition of extra matter to a carbon-oxygen white dwarf at the Chandrasekhar limit may alternatively produce a runaway explosion as a type Ia supernova.
The light from white dwarfs does not arise from internal nuclear reactions but in a thin gaseous atmosphere that slowly leaks away the star's heat into space. The spectral lines arising in this atmosphere are broadened by the extremely high surface gravity, and in extreme cases the light loses enough energy to suffer a measurable gravitational redshift. Over 75% of white dwarfs have hydrogen-rich atmospheres, and are designated DA (see below). Some white dwarfs show no hydrogen at all in their spectra, whereas others are enriched in helium, carbon, and calcium. A few have strong magnetic fields (105 tesla) and several have high rotational velocities. Some are pulsating variables (see ZZ Ceti stars). Novae, recurrent novae, and dwarf novae are close binary stars in which one component is a white dwarf (see cataclysmic variable).
Spectroscopic classification of white dwarfs by spectral type is inadequate because of the variety of surface composition. A classification scheme, introduced in 1983 by E. Sion and others, is based on the following spectral characteristics and temperature information:
DA only lines of neutral hydrogen (H I)
DB neutral helium (He I); no H or metals
DC continuous spectrum
DO ionized helium (He II) strong; no H or He
DZ metal lines only; no H or He
DQ carbon features
White dwarfs are further designated with a temperature index from 0–9, and with appropriate letters for magnetic fields/polarization (H,P), variability (V), and peculiar or unclassified spectra (X).
It has been estimated that there may be 1010 white dwarfs in our Galaxy, many having by now cooled to become black dwarfs. Best known of all white dwarfs is Sirius B, companion to Sirius (αCMa), which was discovered in 1862 by Alvan Clark after F.W. Bessel had predicted its existence (in 1844) from the unusual motion of Sirius. Sirius B has a radius of only 104 km, about twice that of the Earth, but a mass similar to that of the Sun.