The white dwarfs have their own spectral classification scheme, but many CSPNe have O-type spectra. Other stars in the same temperature range include rare O-type subdwarf ( sdO) stars, the central stars of planetary nebulae (CSPNe), and white dwarfs. Because of their high temperatures the luminosities of main sequence O-type stars range from 10,000 times the Sun to around 1,000,000 times, giants from 100,000 times the Sun to over 1,000,000, and supergiants from about 200,000 times the Sun to several million times. They have characteristic surface temperatures ranging from 30,000 to 52,000 K, emit intense ultraviolet light, and so appear in the visible spectrum as bluish-white. Class O spectral standard stars Ĭharacteristics The Trifid Nebula (M20) is sculpted and lit by the luminous O7.5III star visible at its centre in this infrared image. Bright giant luminosity classes are not defined for stars hotter than O6. Subgiant spectral types are not defined for types O2, O2.5, or O3. For spectral types O2 to O5.5, supergiants are not split into Ia/Iab/Ib sub-types. In some cases, a standard star has not been defined. The following table gives one of the standard stars for each spectral type. To help with the classification of O-type stars, standard examples are listed for most of the defined types. The line's presence is thought to indicate extreme youth the "z" stands for zero-age. Stars of types O3 to O8 are classified as luminosity class sub-type Vz if they have a particularly strong 468.6 nm ionised helium line. The increasing strength of Si 3+ emission is also an indicator of increasing luminosity and this is the primary means of assigning luminosity classes to the late O-type stars. At intermediate O5–O8 classes, the distinction between O((f)) main sequence, O(f) giants, and Of supergiants is well-defined and represents a definite increase in luminosity. At O2–O4, the distinction between main sequence and supergiant stars is narrow and may not even represent true luminosity or evolutionary differences. Luminosity class V, main-sequence stars, generally have weak or missing emission lines, with giants and supergiants showing increasing emission line strength. These are indicated by the "f" suffix on the spectral type, with "f" alone indicating N 2+ and He + emission, "(f)" meaning the He emission is weak or absent, "((f))" meaning the N emission is weak or absent, "f*" indicating the addition of very strong N 3+ emission, and "f+" the presence of Si 3+ emission. The luminosity classes of O-type stars are assigned on the relative strengths of the He + emission lines and certain ionised nitrogen and silicon lines. The very hottest O-type stars have such weak neutral He lines that they must be separated on the relative strength of the N 2+ and N 3+ lines. The O7 class is defined where the 454.1-nanometer He + and 447.1-nanometer He 0 lines have equal strength. The key lines are the prominent He + lines at 454.1 nm and 420.0 nm, which vary from very weak at O9.5 to very strong in O2–O7, and the He 0 lines at 447.1 nm and 402.6 nm, which vary from absent in O2/3 to prominent in O9.5. O-type stars are classified by the relative strength of certain spectral lines. Furthermore, O-type stars often occur in multiple star systems, where their evolution is more difficult to predict due to mass transfer and the possibility of component stars exploding as supernovae at different times. These stars illuminate any surrounding material and are largely responsible for the distinct coloration of a galaxy's arms. O-type stars are typically located in regions of active star formation, such as the spiral arms of a spiral galaxy or a pair of galaxies undergoing collision and merger (such as the Antennae Galaxies). Most of these stars are young massive main sequence, giant, or supergiant stars, but some central stars of planetary nebulae, old low-mass stars near the end of their lives, also usually have O spectra. Due to their high mass, O-type stars end their lives rather quickly in violent supernova explosions, resulting in black holes or neutron stars. Stars of this type are very rare, but because they are very bright, they can be seen at great distances and four of the 90 brightest stars as seen from Earth are O type. Stars of this type have strong absorption lines of ionised helium, strong lines of other ionised elements, and hydrogen and neutral helium lines weaker than spectral type B. They have temperatures in excess of 30,000 kelvin (K). Stellar classification Relative size of O-type stars with other main-sequence starsĪn O-type star is a hot, blue-white star of spectral type O in the Yerkes classification system employed by astronomers.
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