Wolf–Rayet star
Wolf–Rayet stars, often abbreviated as WR stars, are a rare heterogeneous set of stars with unusual spectra showing prominent broad emission lines of ionised helium and highly ionised nitrogen or carbon. The spectra indicate very high surface enhancement of heavy elements, depletion of hydrogen, and strong stellar winds. The surface temperatures of known Wolf–Rayet stars range from 20,000 K to around 210,000 K, hotter than almost all other kinds of stars. They were previously called W-type stars referring to their spectral classification.
Classic Wolf–Rayet stars are evolved, massive stars that have completely lost their outer hydrogen and are fusing helium or heavier elements in the core. A subset of the population I WR stars show hydrogen lines in their spectra and are known as WNh stars; they are young extremely massive stars still fusing hydrogen at the core, with helium and nitrogen exposed at the surface by strong mixing and radiation-driven mass loss. A separate group of stars with WR spectra are the central stars of planetary nebulae, post-asymptotic giant branch stars that were similar to the Sun while on the main sequence, but have now ceased fusion and shed their atmospheres to reveal a bare carbon-oxygen core.
All Wolf–Rayet stars are highly luminous objects due to their high temperatures—thousands of times the bolometric luminosity of the Sun for the CSPNe, for the population I WR stars, to for the WNh stars—although not exceptionally bright visually since most of their radiation output is in the ultraviolet.
The naked-eye star systems γ Velorum and θ Muscae both contain Wolf-Rayet stars, and two of the most massive known stars, BAT99-98 and R136a1 in 30 Doradus, are also Wolf–Rayet stars.
Observation history
In 1867, using the 40 cm Foucault telescope at the Paris Observatory, astronomers Charles Wolf and Georges Rayetdiscovered three stars in the constellation Cygnus that displayed broad emission bands on an otherwise continuous spectrum.
Most stars only display absorption lines or bands in their spectra, as a result of overlying elements absorbing light energy at specific frequencies, so these were clearly unusual objects.
The nature of the emission bands in the spectra of a Wolf–Rayet star remained a mystery for several decades. E.C. Pickering theorized that the lines were caused by an unusual state of hydrogen, and it was found that this "Pickering series" of lines followed a pattern similar to the Balmer series when half-integer quantum numbers were substituted. It was later shown that these lines resulted from the presence of helium, the chemical element having just been discovered in 1868.
Pickering noted similarities between Wolf–Rayet spectra and nebular spectra, and this similarity led to the conclusion that some or all Wolf–Rayet stars were the central stars of planetary nebulae.
By 1929, the width of the emission bands was being attributed to Doppler broadening, and hence the gas surrounding these stars must be moving with velocities of 300–2400 km/s along the line of sight. The conclusion was that a Wolf–Rayet star is continually ejecting gas into space, producing an expanding envelope of nebulous gas. The force ejecting the gas at the high velocities observed is radiation pressure.
It was well known that many stars with Wolf–Rayet type spectra were the central stars of planetary nebulae, but also that many were not associated with an obvious planetary nebula or any visible nebulosity at all.
In addition to helium, Carlyle Smith Beals identified emission lines of carbon, oxygen and nitrogen in the spectra of Wolf–Rayet stars.
In 1938, the International Astronomical Union classified the spectra of Wolf–Rayet stars into types WN and WC, depending on whether the spectrum was dominated by lines of nitrogen or carbon-oxygen respectively.
In 1969, several CSPNe with strong oxygen VI emissions lines were grouped under a new "OVI sequence", or just OVI type. Similar stars not associated with planetary nebulae were described shortly after and the WO classification was adopted for them. The OVI stars were subsequently classified as stars, consistent with the population I WR stars.
The understanding that certain late, and sometimes not-so-late, WN stars with hydrogen lines in their spectra are at a different stage of evolution from hydrogen-free WR stars has led to the introduction of the term WNh to distinguish these stars generally from other WN stars. They were previously referred to as WNL stars, although there are late-type WN stars without hydrogen as well as WR stars with hydrogen as early as WN5.
Classification
Wolf–Rayet stars were named on the basis of the strong broad emission lines in their spectra, identified with helium, nitrogen, carbon, silicon, and oxygen, but with hydrogen lines usually weak or absent. Initially simply referred to as class W or W-type stars, the classification was then split into stars with dominant lines of ionised nitrogen and those with dominant lines of ionised carbon and sometimes oxygen, referred to as WN and WC respectively.The two classes WN and WC were further split into temperature sequences WN5–WN8 and WC6–WC8 based on the relative strengths of the 541.1 nm HeII and 587.5 nm HeI lines. Wolf–Rayet emission lines frequently have a broadened absorption wing suggesting circumstellar material. A WO sequence has also been separated from the WC sequence for even hotter stars where emission of ionised oxygen dominates that of ionised carbon, although the actual proportions of those elements in the stars are likely to be comparable. WC and WO spectra are formally distinguished based on the presence or absence of CIII emission. WC spectra also generally lack the OVI lines that are strong in WO spectra.
The WN spectral sequence was expanded to include WN2–WN9, and the definitions refined based on the relative strengths of the NIII lines at 463.4–464.1 nm and 531.4 nm, the NIV lines at 347.9–348.4 nm and 405.8 nm, and the NV lines at 460.3 nm, 461.9 nm, and 493.3–494.4 nm.
These lines are well separated from areas of strong and variable He emission and the line strengths are well correlated with temperature. Stars with spectra intermediate between WN and Ofpe have been classified as WN10 and WN11 although this nomenclature is not universally accepted.
The type WN1 was proposed for stars with neither NIV nor NV lines, to accommodate Brey 1 and Brey 66 which appeared to be intermediate between WN2 and WN2.5.
The relative line strengths and widths for each WN sub-class were later quantified, and the ratio between the 541.1 nm HeII and 587.5 nm, HeI lines was introduced as the primary indicator of the ionisation level and hence of the spectral sub-class. The need for WN1 disappeared and both Brey 1 and Brey 66 are now classified as WN3b. The somewhat obscure WN2.5 and WN4.5 classes were dropped.
| Spectral Type | Original criteria | Updated criteria | Other features |
| WN2 | NV weak or absent | NV and NIV absent | Strong HeII, no HeI |
| WN2.5 | NV present, NIV absent | Obsolete class | |
| WN3 | NIV ≪ NV, NIII weak or absent | HeII/HeI > 10, HeII/CIV > 5 | Peculiar profiles, unpredictable NV strength |
| WN4 | NIV ≈ NV, NIII weak or absent | 4 < HeII/HeI < 10, NV/NIII > 2 | CIV present |
| WN4.5 | NIV > NV, NIII weak or absent | Obsolete class | |
| WN5 | NIII ≈ NIV ≈ NV | 1.25 < HeII/HeI < 8, 0.5 < NV/NIII < 2 | NIV or CIV > HeI |
| WN6 | NIII ≈ NIV, NV weak | 1.25 < HeII/HeI < 8, 0.2 < NV/NIII < 0.5 | CIV ≈ HeI |
| WN7 | NIII > NIV | 0.65 < HeII/HeI < 1.25 | Weak P-Cyg profile HeI, HeII > NIII, CIV > HeI |
| WN8 | NIII ≫ NIV | HeII/HeI < 0.65 | Strong P-Cyg profile HeI, HeII ≈ NIII, CIV weak |
| WN9 | NIII > NII, NIV absent | NIII > NII, NIV absent | P-Cyg profile HeI |
| WN10 | NIII ≈ NII | NIII ≈ NII | H Balmer, P-Cyg profile HeI |
| WN11 | NIII weak or absent, NII present | NII ≈ HeII, NIII weak or absent, | H Balmer, P-Cyg profile HeI, FeIII present |
The WC spectral sequence was expanded to include WC4–WC11, although some older papers have also used WC1–WC3. The primary emission lines used to distinguish the WC sub-types are CII 426.7 nm, CIII at 569.6 nm, CIII/IV 465.0 nm, CIV at 580.1–581.2 nm, and the OV blend at 557.2–559.8 nm. The sequence was extended to include WC10 and WC11, and the subclass criteria were quantified based primarily on the relative strengths of carbon lines to rely on ionisation factors even if there were abundance variations between carbon and oxygen.
For WO-type stars the main lines used are CIV at 580.1 nm, OIV at 340.0 nm, OV blend at 557.2–559.8 nm, OVI at 381.1–383.4 nm, OVII at 567.0 nm, and OVIII at 606.8 nm. The sequence was expanded to include WO5 and quantified based the relative strengths of the OVI/CIV and OVI/OV lines.
A later scheme, designed for consistency across classical WR stars and CSPNe, returned to the WO1 to WO4 sequence and adjusted the divisions.
Detailed modern studies of Wolf–Rayet stars can identify additional spectral features, indicated by suffixes to the main spectral classification:
- h for hydrogen emission;
- ha for hydrogen emission and absorption;
- o for no hydrogen emission;
- w for weak lines;
- s for strong lines;
- b for broad strong lines;
- d for dust.
The hotter WR spectral sub-classes are described as early and the cooler ones as late, consistent with other spectral types. WNE and WCE refer to early type spectra while WNL and WCL refer to late type spectra, with the dividing line approximately at sub-class six or seven. There is no such thing as a late WO-type star. There is a strong tendency for WNE stars to be hydrogen-poor while the spectra of WNL stars frequently include hydrogen lines.
Spectral types for the central stars of planetary nebulae are qualified by surrounding them with square brackets. They are almost all of the WC sequence with the known stars representing the hot extension of the carbon sequence. There are also a small number of and types, only discovered quite recently.
Their formation mechanism is as yet unclear. Temperatures of the planetary nebula central stars tend to the extremes when compared to population I WR stars, so and are common and the sequence has been extended to . The and types have distinctive spectra with narrow emission lines and no HeII and CIV lines.
Certain supernovae observed before their peak brightness show WR spectra.
This is due to the nature of the supernova at this point: a rapidly expanding helium-rich ejecta similar to an extreme Wolf–Rayet wind. The WR spectral features only last a matter of hours, the high ionisation features fading by maximum to leave only weak neutral hydrogen and helium emission, before being replaced with a traditional supernova spectrum. It has been proposed to label these spectral types with an "X", for example XWN5. Similarly, classical novae develop spectra consisting of broad emission bands similar to a Wolf–Rayet star. This is caused by the same physical mechanism: rapid expansion of dense gases around an extremely hot central source.