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The 'main sequence' of the Hertzsprung-Russell diagram is the curve along which the majority of stars are located. Stars on this band are known as 'main-sequence stars' or 'dwarf stars'.
This line is so pronounced because both the spectral type and the luminosity depend only on a star's mass (to zeroth order) as long as it is fusing hydrogen—and that is what almost all stars spend most of their "active" life doing.
The main sequence does not follow a completely even curve; this is primarily because of the observational uncertainties which mainly affect the distance of the star in question but range all the way to unresolved binary stars.
However, even perfect observations would lead to a fuzzy main sequence, because mass is not a star's only parameter. Chemical composition and—related—its evolutionary status also move a star slightly on the main sequence, as do close companions, rotation, or magnetic fields, to name just a few factors. Actually, there are very metal-poor stars (subdwarfs) that lie just below the main sequence although they are fusing hydrogen, thus marking the lower edge of the main sequence's fuzziness due to chemical composition.
Astronomers will sometimes refer to the "'zero age main sequence'", or 'ZAMS'. This is a line calculated by computer models of where a star will be when it begins hydrogen fusion; its brightness and surface temperature typically increase from this point with age. Stars usually enter and leave the main sequence from about when they are born or when they are starting to die, respectively.
Our Sun is a main-sequence star—it has been one for about 4.5 billion years and will continue to be one for another 4.5 billion years. It has the spectral classification of G2 V. After the hydrogen supply in the core is exhausted, it will expand to become a red giant.
The total main sequence lifetime of a star can be estimated from its mass relative to the Sun's as follows:^[1]
:
ight ]^{2.5}mbox{ years}
where is the mass of the Sun, $M$ is the mass of the star and $au\_\{ms\}$ is the star's estimated main sequence lifetime in years. The lightest stars, of less than a tenth of solar mass, may last over a trillion years. However, this estimate poorly matches the lifetime of the heaviest stars, which last at least a few million years.

Contents

Main sequence data

See also

References

External links

Main sequence data

The table below shows typical values for stars along the main sequence. The values of luminosity (L), radius (R), and mass (M) are relative to the Sun. The actual values for a star may vary by as much as 20-30%. The coloration of the stellar class column gives an approximate representation of the star's photographic color. A popular mnemonic for memorizing the sequence is "Oh Be A Fine Girl/Guy, Kiss Me".
:

Stellar Class	Radius	Mass	Luminosity	Temperature
	R/R☉	M/M☉	L/L☉	K
O2	16	158	2,000,000	54,000
O5	14	58	800,000	46,000
B0	5.7	16	16,000	29,000
B5	3.7	5.4	750	15,200
A0	2.3	2.6	63	9,600
A5	1.8	1.9	24	8,700
F0	1.5	1.6	9.0	7,200
F5	1.2	1.35	4.0	6,400
G0	1.05	1.08	1.45	6,000
G2	1.0	1.0	1.0	5,700
G5	0.98	0.95	0.70	5,500
K0	0.89	0.83	0.36	5,150
K5	0.75	0.62	0.18	4,450
M0	0.64	0.47	0.075	3,850
M5	0.36	0.25	0.013	3,200
M8	0.15	0.10	0.0008	2,500
M9.5	0.10	0.08	0.0001	1,900

See also

★ Instability

References

1. Stellar evolution on the main sequence


★ Massey, Philip and Michael R. Meyer. "Stellar Masses." ''The Encyclopedia of Astronomy and Astrophysics.'' Ed. Paul Murdin. London: Institute of Physics Publishing Ltd and Nature Publishing Group, 2001. 3103-09. ISBN 1-56159-268-4

External links

★ Table of Features of the "Life Zones" of Main Sequence Stars

★ A java based applet for stellar evolution.