Stellar classification

The Yerkes spectral classification, also called the MKK system from the authors' initials, is a system of stellar spectral classification introduced in 1943 by William Wilson Morgan, Phillip C. Keenan and Edith Kellman from Yerkes Observatory. This classification is based on spectral lines sensitive to stellar surface gravity which is related to luminosity, as opposed to the Harvard classification which is based on surface temperature. Later, in 1953, after some revisions of list of standard stars and classification criteria, the scheme was named MK (by William Wilson Morgan and Phillip C. Keenan initials).

Since the radius of a giant star is much larger than a dwarf star while their masses are roughly comparable, the gravity and thus the gas density and pressure on the surface of a giant star are much lower than for a dwarf. These differences manifest themselves in the form of luminosity effects which affect both the width and the intensity of spectral lines which can then be measured. Denser stars with higher surface gravity will exhibit greater pressure broadening of spectral lines.

A number of different luminosity classes are distinguished:

• I supergiants
• Ia-0 (hypergiants or extremely luminous supergiants (later addition)), Example: Eta Carinae (spectrum-peculiar)
• Ia (luminous supergiants), Example: Deneb (spectrum is A2Ia)
• Iab (intermediate luminous supergiants)
• Ib (less luminous supergiants), Example: Betelgeuse (spectrum is M2Ib)
• II bright giants
• IIa, Example: β Scuti (HD 173764) (spectrum is G4 IIa)
• IIab Example: HR 8752 (spectrum is G0Iab:)
• IIb, Example: HR 6902 (spectrum is G9 IIb)
• III normal giants
• IIIa, Example: ρ Persei (spectrum is M4 IIIa)
• IIIab Example: δ Reticuli (spectrum is M2 IIIab)
• IIIb, Example: Pollux (spectrum is K2 IIIb)
• IV subgiants
• IVa, Example: ε Reticuli (spectrum is K1-2 IVa-III)

• IVb, Example: HR 672 A (spectrum is G0.5 IVb)

• Va, Example: AD Leonis (spectrum M4Vae)

• Vb, Example: 85 Pegasi A (spectrum G5 Vb)

Marginal cases are allowed; for instance a star classified as Ia0-Ia would be a very luminous supergiant, verging on hypergiant. Examples are below. The spectral type of the star is not a factor.

Spectral types

The following illustration represents star classes with the colors very close to those actually perceived by the human eye. The relative sizes are for main sequence or "dwarf" stars.

Class O

Examples: Zeta Orionis, Zeta Puppis, Lambda Orionis, Delta Orionis

Class B

Class B stars are extremely luminous and blue. Their spectra have neutral helium, which are most prominent at the B2 subclass, and moderate hydrogen lines. Ionized metal lines include Mg II and Si II. As O and B stars are so powerful, they only live for a very short time, and thus they do not stray far from the area in which they were formed. These stars tend to cluster together in what are called OB associations, which are associated with giant molecular clouds. The Orion OB1 association occupies a large portion of a spiral arm of our galaxy and contains many of the brighter stars of the constellation Orion. They constitute about 1 in 800 main sequence stars in the solar neighborhood —rare, but much more common than those of class O.

Examples: Rigel, Spica, the brighter Pleiades

Class A

Examples: Vega, Sirius, Deneb

Class F

Examples: Arrakis, Canopus, Procyon

Class G

Class G stars are probably the best known, if only for the reason that our Sun is of this class. Most notable are the H and K lines of Ca II, which are most prominent at G2. They have even weaker hydrogen lines than F, but along with the ionized metals, they have neutral metals. There is a prominent spike in the G band of CH molecules. G is host to the "Yellow Evolutionary Void". Supergiant stars often swing between O or B (blue) and K or M (red). While they do this, they do not stay for long in the G classification as this is an extremely unstable place for a supergiant to be. G stars represent about 1 in 13 of the main sequence stars in the solar neighborhood.

Examples: Sun, Alpha Centauri A, Capella, Tau Ceti

Class K

Examples: Alpha Centauri B, Epsilon Eridani, Arcturus, Aldebaran

Class M

Class M is by far the most common class. About 76% of the main sequence stars in the solar neighborhood are red dwarfs (78.6% if we include all stars: see the note under Class O), such as Proxima Centauri. M is also host to most giants and some supergiants such as Antares and Betelgeuse, as well as Mira variables. The late-M group holds hotter brown dwarfs that are above the L spectrum. This is usually in the range of M6.5 to M9.5. The spectrum of an M star shows lines belonging to molecules and all neutral metals but hydrogen lines are usually absent. Titanium oxide can be strong in M stars, usually dominating by about M5. Vanadium oxide bands become present by late M.

Example: Betelgeuse (supergiant)

Examples: Proxima Centauri, Barnard's star, Gliese 581 (red dwarf)

Example: LEHPM 2-59 (subdwarf)

Examples: Teide 1 (field brown dwarf), GSC 08047-00232 B (companion brown dwarf)

Extended spectral types

A number of new spectral types have been taken into use from newly discovered types of stars.

Hot blue emission star classes

Spectra of some very hot and bluish stars exhibit marked emission lines from carbon or nitrogen, or sometimes oxygen.

Class W: Wolf-Rayet

Class W or WR represents the superluminous Wolf-Rayet stars, notably unusual since they have mostly helium in their atmospheres instead of hydrogen. They are thought to be dying supergiants with their hydrogen layer blown away by hot stellar winds caused by their high temperatures, thereby directly exposing their hot helium shell. Class W is subdivided into subclasses WC (WCE early-type, WCL late-type), WN (WNE early-type, WNL late-type), and WO according to the dominance of carbon, nitrogen, or oxygen emission in their spectra (and outer layers).

• W: Up to 70,000 K

Example: Gamma Velorum A (WC)

Example: WR124 (WN)

Example: WR93B (WO)

Classes OC, ON, BC, BN: Wolf-Rayet related O and B stars

Intermediary between the genuine Wolf-Rayets and ordinary hot stars of classes O and early B, there are OC, ON, BC and BN stars. They seem to constitute a short continuum from the Wolf-Rayets into the ordinary OBs.

Example: HD 152249 (OC)

Example: HD 105056 (ON)

Example: HD 2905 (BC)

Example: HD 163181 (BN)

The "class" OB

In lists of spectra, the "spectrum OB" may occur. This is in fact not a spectrum, but a marker which means that "the spectrum of this star is unknown, but it belongs to an OB association, so probably either a class O or class B star, or perhaps a fairly hot class A star."

Cool red and brown dwarf classes

The novel spectral types L and T were created to classify infrared spectra of cool stars. This included both red dwarfs and brown dwarfs which are very faint in the visual spectrum. The hypothetical spectral type Y has been reserved for objects cooler than T dwarfs which have spectra that are qualitatively distinct from T dwarfs.

Class L

Class L dwarfs get their designation because they are cooler than M stars and L is the remaining letter alphabetically closest to M. L does not mean lithium dwarf; a large fraction of these stars do not have lithium in their spectra. Some of these objects have mass large enough to support hydrogen fusion, but some are of substellar mass and do not, so collectively these objects should be referred to as L dwarfs, not L stars. They are a very dark red in color and brightest in infrared. Their atmosphere is cool enough to allow metal hydrides and alkali metals to be prominent in their spectra. Due to low gravities in giant stars, TiO- and VO-bearing condensates never form. Thus, larger L-type stars can never form in an isolated environment. It may be possible for these L-type supergiants to form through stellar collisions, however, an example of which is V838 Monocerotis.

• L: 1,300–2,000 K, dwarfs (some stellar, some substellar) with metal hydrides and alkali metals prominent in their spectra.

Example: VW Hyi

Example: 2MASSW J0746425+2000321 binary

Component A is an L dwarf star

Component B is an L brown dwarf

Example: V838 Monocerotis (supergiants)

Class T: methane dwarfs

Class T dwarfs are cool brown dwarfs with surface temperatures of between approximately 700 and 1,300 K. Their emission peaks in the infrared. Methane is prominent in their spectra.

• T: ~700-1,300 K, cooler brown dwarfs with methane in the spectrum

Examples: SIMP 0136 (the brightest T dwarf discovered in northern hemisphere)

Examples: Epsilon Indi Ba & Epsilon Indi Bb

Class T and L could be more common than all the other classes combined if recent research is accurate. From studying the number of proplyds (protoplanetary discs, clumps of gas in nebulae from which stars and solar systems are formed) then the number of stars in the galaxy should be several orders of magnitude higher than what we know about. It is theorized that these proplyds are in a race with each other. The first one to form will become a proto-star, which are very violent objects and will disrupt other proplyds in the vicinity, stripping them of their gas. The victim proplyds will then probably go on to become main sequence stars or brown dwarf stars of the L and T classes, but quite invisible to us. Since they live so long, these smaller stars will accumulate over time.

Class Y

• Y: < 700 K, ultra-cool brown dwarfs (theoretical)

Carbon related late giant star classes

Carbon related stars are stars whose spectra indicate production of carbon by helium triple-alpha fusion. With increased carbon abundance, and some parallel s-process heavy element production, the spectra of these stars are becoming increasingly deviant from the usual late spectral classes G, K and M. The giants among those stars are presumed to produce this carbon themselves, but not too few of this class of stars are believed to be double stars whose odd atmosphere once was transferred from a former carbon star companion that is now a white dwarf.

Class C: carbon stars

Originally classified as R and N stars, these are also known as 'carbon stars'. These are red giants, near the end of their lives, in which there is an excess of carbon in the atmosphere. The old R and N classes ran parallel to the normal classification system from roughly mid G to late M. These have more recently been remapped into a unified carbon classifier C, with N0 starting at roughly C6. Another subset of cool carbon stars are the J-type stars, which are characterized by the strong presence of molecules of ¹³CN in addition to those of ¹²CN. A few dwarf (that is, main sequence) carbon stars are known, but the overwhelming majority of known carbon stars are giants or supergiants.

• C: Carbon stars, e.g. R CMi
• C-R: Formerly a class on its own representing the carbon star equivalent of late G to early K stars. Example: S Camelopardalis
• C-N: Formerly a class on its own representing the carbon star equivalent of late K to M stars. Example: R Leporis
• C-J: A subtype of cool C stars with a high content of ¹³C. Example: Y Canum Venaticorum
• C-H: Population II analogues of the C-R stars. Examples: V Ari, TT CVn
• C-Hd: Hydrogen-Deficient Carbon Stars, similar to late G supergiants with CH and C₂ bands added. Example: HD 137613

Class S

Class S stars have zirconium oxide lines in addition to (or, rarely, instead of) those of titanium oxide, and are in between the Class M stars and the carbon stars. S stars have excess amounts of zirconium and other elements produced by the s-process, and have their carbon and oxygen abundances closer to equal than is the case for M stars. The latter condition results in both carbon and oxygen being locked up almost entirely in carbon monoxide molecules. For stars cool enough for carbon monoxide to form that molecule tends to "eat up" all of whichever element is less abundant, resulting in "leftover oxygen" (which becomes available to form titanium oxide) in stars of normal composition, "leftover carbon" (which becomes available to form the diatomic carbon molecules) in carbon stars, and "leftover nothing" in the S stars. The relation between these stars and the ordinary M stars indicates a continuum of carbon abundance. Like carbon stars, nearly all known S stars are giants or supergiants.

Examples: S Ursae Majoris, HR 1105

Classes MS and SC: intermediary carbon related classes

In between the M class and the S class, border cases are named MS stars. In a similar way border cases between the S class and the C-N class are named SC or CS. The sequence M → MS → S → SC → C-N is believed to be a sequence of increased carbon abundance with age for carbon stars in the asymptotic giant branch.

Examples: R Serpentis, ST Monocerotis (MS)

Examples: CY Cygni, BH Crucis (SC)

White dwarf classifications

The class D is the modern classification used for white dwarfs, low-mass stars that are no longer undergoing nuclear fusion and have shrunk to planetary size, slowly cooling down. Class D is further divided into spectral types DA, DB, DC, DO, DQ, DX, and DZ. The letters are not related to the letters used in the classification of other stars, but instead indicate the composition of the white dwarf's visible outer layer or atmosphere.

Examples: Sirius B (DA2), Procyon B (DA4), Van Maanen's star (DZ7)^{, Table 1}

The white dwarf types are as follows:

• DA: a hydrogen-rich atmosphere or outer layer, indicated by strong Balmer hydrogen spectral lines.
• DB: a helium-rich atmosphere, indicated by neutral helium, He I, spectral lines.
• DO: a helium-rich atmosphere, indicated by ionized helium, He II, spectral lines.
• DQ: a carbon-rich atmosphere, indicated by atomic or molecular carbon lines.
• DZ: a metal-rich atmosphere, indicated by metal spectral lines.
• DC: no strong spectral lines indicating one of the above categories.
• DX: spectral lines are insufficiently clear to classify into one of the above categories.

The type is followed by a number giving the white dwarf's surface temperature. This number is a rounded form of 50400/T_eff, where T_eff is the effective surface temperature, measured in kelvins. Originally, this number was rounded to one of the digits 1 through 9, but more recently fractional values have started to be used, as well as values below 1 and above 9.

Two or more of the type letters may be used to indicate a white dwarf which displays more than one of the spectral features above. Also, the letter V is used to indicate a variable white dwarf.

Extended white dwarf spectral types:

• DAB: a hydrogen- and helium-rich white dwarf displaying neutral helium lines.
• DAO: a hydrogen- and helium-rich white dwarf displaying ionized helium lines.
• DAZ: a hydrogen-rich metallic white dwarf.
• DBZ: a helium-rich metallic white dwarf.

Variable star designations:

• DAV or ZZ Ceti: a hydrogen-rich pulsating white dwarf.^{, pp. 891, 895}
• DBV or V777 Her: a helium-rich pulsating white dwarf.^{, p. 3525}
• GW Vir, DOV or PNNV: a hot helium-rich pulsating white dwarf (or pre-white dwarf.)^{, §1.1, 1.2;}

Non-stellar spectral types: Class P & Q

Finally, the classes P and Q are occasionally used for certain non-stellar objects. Type P objects are planetary nebulae and type Q objects are novae.

Spectral peculiarities

Additional nomenclature, in the form of lower-case letters, can follow the spectral type to indicate peculiar features of the spectrum.

For example, Epsilon Ursae Majoris is listed as spectral type A0pCr, indicating general classification A0 with a strong emission lines of the element chromium. There are several common classes of chemically peculiar stars, where the spectral lines of a number of elements appear abnormally strong.

Photometric classification

Stars can also be classified using photometric data from any photometric system. For example, we can calibrate color index diagrams of U−B and B−V in the UBV system according to spectral and luminosity classes. Nevertheless, this calibration is not straightforward, because many effects are superimposed in such diagrams: interstellar reddening, color changes due to metallicity, and the blending of light from binary and multiple stars.

Photometric systems with more colors and narrower passbands allow a star's class, and hence physical parameters, to be determined more precisely. The most accurate determination comes of course from spectral measurements, but there is not always enough time to get qualitative spectra with high signal-to-noise ratio.

See also

• Stellar evolution
• Stellar associations
• Metallicity
• Astrograph
• H-R diagram

References

External links

• Libraries of stellar spectra, D. Montes, UCM
• Webfooted Astronomer
• The rate of period change in pulsating DB white dwarf stars, A. H. Corsico, L. G. Althaus, has the DAV, DBV, & DOV explanation.
• The Close DAO+dM Binary RE J0720-318: A Stratified White Dwarf with a Thin H Layer and a Possible Circumbinary Disk DAO type White Dwarf.
• The Spatial Distribution and Kinematics of Cool Metallic Line White Dwarfs, has DAZ and DBZ spectrums
• A K-Band Spectral Atlas of Wolf-Rayet Stars, has WC, WN, and WO spectrums
• Properties of the WO Wolf-Rayet stars, has WO spectrum ranging from WO1 to WO5
• Spectral Types for Hipparcos Catalogue Entries
• , has the luminous subclasses.
• Discovery of a Very Young Field L Dwarf, 2MASS J01415823-4633574, J. Davy Kirkpatrick et al.