S Doradus
Observation data Epoch J2000 Equinox J2000 | |
---|---|
Constellation | Dorado |
Right ascension | 05h 18m 14.3572s[1] |
Declination | −69° 15′ 01.148″[1] |
Apparent magnitude (V) | 8.6 – 11.5[2] |
Characteristics | |
Spectral type | B8/9eq – F0/5:Iae[3] |
U−B color index | –0.98[4] |
B−V color index | +0.11[4] |
Variable type | S Doradus[2] |
Absolute magnitude (MV) | –7.6 (1965) –10.0 (1989)[6] |
Details | |
Mass | 24+16 −2[7] M☉ |
1989 (maximum) | |
Radius | 380[8] R☉ |
Luminosity | 910,000[6] L☉ |
Surface gravity (log g) | 0.6[8] cgs |
Temperature | 8,500[6] K |
1985 (minimum) | |
Radius | 100[8] R☉ |
Luminosity | 1,400,000[8] L☉ |
Surface gravity (log g) | 1.6[8] cgs |
Temperature | 20,000[8] K |
1965 (deep minimum) | |
Luminosity | 2,000,000[6] L☉ |
Temperature | 35,000[6] K |
AAVSO 0518-69. | |
Database references | |
SIMBAD | data |
S Doradus (also known as S Dor) is one of the brightest stars in the Large Magellanic Cloud (LMC), a satellite galaxy of the Milky Way, located roughly 160,000 light-years away. The star is a luminous blue variable, and one of the most luminous stars known, having a luminosity varying widely above and below 1,000,000 times the luminosity of the Sun, although it is too far away to be seen with the naked eye.
History
S Doradus was noted in 1897 as an unusual and variable star, of
S Dor was observed many times over the coming decades. In 1924, it was described as "P Cygni class" and recorded at photographic magnitude 9.5[11] In 1925, its absolute magnitude was estimated at −8.9.[12] In 1933 it was listed as a 9th-magnitude Beq star with bright hydrogen lines.[13] It was the most luminous star known at that time.[14][15]
In 1943, the variability was interpreted as being due to eclipses of a binary companion, orbiting with a period of 40 years.
By 1969 the nature of S Doradus was still uncertain, considered possibly to be a pre-main-sequence star,[20] but during the next decade the consensus settled on the S Doradus type variables and Hubble-Sandage variables being evolved massive supergiants.[21][22] They were eventually given the name "luminous blue variables" in 1984, coined in part because of the similarity of the acronym LBV to the well-defined LPV class of variable stars.[23] The classification system defined for the General Catalogue of Variable Stars pre-dated this and so the acronym SDOR is used for LBVs.[24]
Surroundings
S Doradus is the brightest member of the open cluster
There are several compact clusters near S Doradus, within the general NGC 1910/LH41 association. The closest is less than four arc-minutes away, contains two out of the three WO stars in the entire LMC, and the entire cluster is about the same brightness as S Doradus. A little further away is
S Doradus has a number of close companion stars. The Washington Double Star Catalog lists two 11th-magnitude stars 5″ away, which at the distance of the LMC is about four light years.[29] A much closer companion has been found using the Hubble Space Telescope Fine Guidance Sensor, 1.7″ away and four magnitudes fainter.[30] There are other nearby stars, most notably a 12th-magnitude OB supergiant at 13″.[31]
Variability
This star belongs to its own eponymous
The colour of S Doradus changes as its brightness varies, being bluest when the star is faintest.[8] At the same time, the spectrum shows dramatic changes. It is typically an extreme mid-A supergiant with P Cygni profiles on many lines (e.g. A5eq[19] or A2/3Ia+e[33]). At maximum brightness, the spectrum can become as cool as an F supergiant, with strong ionised metal lines and almost no emission components.[26] At minimum brightness, the spectrum is dominated by emission, particularly forbidden lines of Feii but also helium and other metals. At the deep minima these features are even more pronounced, and Feiii emission also appears.[19]
Attempts to identify regularity in the unpredictable changes of brightness suggest a period of around 100 days for the small amplitude variations near maximum brightness. At minimum brightness, these microvariations are considered to occur with periods as long as 195 days. The slower variations have been characterised with a period of 6.8 years, with an interval of 35–40 years between deep minima. The microvariations are similar to the brightness changes shown by
The instability strip
S Doradus variables (LBVs) show distinct quiescent and outburst states. During the quiescent phase, LBVs lie along a diagonal band in the
The standard theory is that LBV outbursts occur when the mass loss increases and an extremely dense stellar wind creates a pseudo-photosphere. The temperature drops until the wind opacity starts to decrease, meaning all LBV outbursts reach a temperature around 8,000–9,000 K. The bolometric luminosity during outbursts is considered to remain largely unchanged, but the visual luminosity increases as radiation shifts from the ultraviolet into the visual range.[35] Detailed investigations have shown that some LBVs appear to change luminosity from minimum to maximum. S Doradus has been calculated to be less luminous at maximum brightness (minimum temperature), possibly as a result of potential energy going into expansion of a substantial portion of the star. AG Carinae and HR Carinae show similar luminosity decreases in some studies, but in the most convincing case AFGL 2298 increased its luminosity during its outbursts.[8]
Rare larger eruptions can appear as long-lasting under-luminous supernovae, and have been termed supernova impostors. The cause of the eruptions is unknown, but the star survives and may experience multiple eruptions. Eta Carinae and P Cygni are the only known examples in the Milky Way, and S Doradus has not shown such an eruption.[36]
Stellar properties
The temperature of an LBV is difficult to determine because the spectra are so peculiar and the standard colour calibrations don't apply, so the luminosity changes associated with brightness variations cannot be calculated accurately. Within the margins of error, it has often been assumed that the luminosity stays constant during all LBV outbursts. This is likely if the outburst consists only of an opaque stellar wind forming a pseudo-photosphere to mimic a larger cooler star.[38]
Better atmospheric physics and observations of luminosity changes during some LBV outbursts have cast doubt on the original models.[39] The atmosphere of S Doradus has been modeled in detail between a normal minimum at magnitude 10.2 in 1985 and a maximum at magnitude 9.0 in 1989. The temperature was calculated to drop from 20,000 K to 9,000 K, and the luminosity dropped from 1,400,000 L☉ to 708,000 L☉. This corresponds to an increase in the radius of the visible surface of the star from 100 R☉ to 380 R☉.[8] A simpler calculation of the variation from the deep 1965 minimum at magnitude 11.5 to the 1989 maximum gives a temperature drop from 35,000 K to 8,500 K, and the luminosity drop from 2,000,000 L☉ to 910,000 L☉.[6] For a brief period during the maximum in late 1999, the temperature dropped further to between 7,500 K and 8,500 K, without the brightness changing noticeably. This is normal in other LBVs at maximum and is as cool as they can get, but it has not been seen in S Doradus before, or since.[26] Observations of AG Carinae have shown that any luminosity changes between minimum and maximum may occur abruptly over a small temperature range, with the luminosity approximately constant during the rest of the light curve.[40]
The mass of an LBV is difficult to calculate directly unless it is in a binary system. The surface gravity changes dramatically and is difficult to measure from the peculiar spectral lines, and the radius is poorly defined. LBVs are thought to be the direct predecessors of Wolf–Rayet stars, but may be either just evolved from the main sequence or post-red supergiant stars with much lower masses. In the case of S Doradus, the current mass is likely to be in the range of 20–45 M☉.[7][8]
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