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Review

A Census of B[e] Supergiants

Astronomical Institute, Czech Academy of Sciences, Fričova 298, 251 65 Ondřejov, Czech Republic
Submission received: 7 August 2019 / Revised: 22 September 2019 / Accepted: 25 September 2019 / Published: 29 September 2019
(This article belongs to the Special Issue Luminous Stars in Nearby Galaxies)

Abstract

:
Stellar evolution theory is most uncertain for massive stars. For reliable predictions of the evolution of massive stars and their final fate, solid constraints on the physical parameters, and their changes along the evolution and in different environments, are required. Massive stars evolve through a variety of short transition phases, in which they can experience large mass-loss either in the form of dense winds or via sudden eruptions. The B[e] supergiants comprise one such group of massive transition objects. They are characterized by dense, dusty disks of yet unknown origin. In the Milky Way, identification and classification of B[e] supergiants is usually hampered by their uncertain distances, hence luminosities, and by the confusion of low-luminosity candidates with massive pre-main sequence objects. The extragalactic objects are often mistaken as quiescent or candidate luminous blue variables, with whom B[e] supergiants share a number of spectroscopic characteristics. In this review, proper criteria are provided, based on which B[e] supergiants can be unambiguously classified and separated from other high luminosity post-main sequence stars and pre-main sequence stars. Using these criteria, the B[e] supergiant samples in diverse galaxies are critically inspected, to achieve a reliable census of the current population.

1. Introduction

Massive stars play a major role in the evolution of their host galaxies. Via stellar winds, they strongly enrich the interstellar medium (ISM) with chemically processed material and deposit large amounts of momentum and energy into their surroundings during their entire lifetime, from the main-sequence up to their final fate as spectacular supernova explosions (e.g., [1,2,3]). The released energy provides the ionizing radiation, substantially supplies the global energy budget of the host galaxy and significantly contributes to shaping the local ISM, whereas the released material condenses into molecules and dust, providing the cradles for the next generation of stars and planets (e.g., [4,5]).
Despite their great importance, stellar evolution theory is most uncertain for massive stars due to the often still poor understanding of some physical processes in the stellar interiors (e.g., core convective overshooting, chemical diffusion, internal differential rotation law and angular momentum transport), the excitation and propagation of pulsation instabilities within their atmospheres, the amount of mass loss via stellar (often asymmetric) winds and (irregular) mass ejections, and the role of binarity for certain phases.
From an observational point of view, the post-main sequence domain within the Hertzsprung–Russell (HR) diagram is populated with various types of extreme massive stars. These are found to be in transition phases, in which the stars shed huge amounts of material into their environments, typically via episodic, sometimes even eruptive events. These objects are luminous super- or hypergiants populating the upper part of the HR diagram and spreading from spectral type O to F or even later. The ejected material thereby accumulates in either nebulae, shells, or even disk-like structures.
The mass-loss of massive stars not only critically depends on the physical parameters, such as mass, effective temperature, and rotation speed, but also on the chemical composition of the star. The amount of mass that is lost, within each individual evolutionary phase, determines the fate of the object. It is thus not surprising that relative numbers of various types of massive stars can change drastically among galaxies with different metallicities (e.g., [6]). For reliable predictions of the evolutionary path of massive stars in any environment, solid constraints on the physical parameters, used in modern stellar evolution models, are indispensable. To obtain such constraints, the properties of the members within each class of objects need to be studied in great detail and within a variety of environments. This requires statistically significant samples of stars in each class of objects, suitable for a detailed analysis. The star-forming galaxies within the local Universe, in which the metallicities spread over a factor of about 25 between the most metal poor and the most metal rich representative, are the most ideal sites to tackle this challenge.
This review is devoted to the B[e] supergiants, which comprise one of the various classes of extreme massive stars in transition. The article is structured as follows. First, an overview on the general properties of these stars is given based mostly on the well-studied sample within the Magellanic Clouds (Section 2), followed by a review on how these objects are searched for in various environments (Section 3). A census of the currently known objects in the Local Group galaxies and slightly beyond is presented in Section 4, based on a critical inspection of the properties of the individual candidates. The discussion of the B[e]SG samples and our conclusions are finally summarized in Section 5.

2. B[e] Supergiants

The early-type supergiants include a class of emission-line objects, whose optical spectra display a peculiar character with strong Balmer emission along with narrow emission lines from permitted and forbidden transitions (e.g., [7,8,9,10]). The latter are indicative of a cool and slowly expanding medium. With the advent of ultraviolet (UV) observations taken with the International Ultraviolet Explorer (IUE), these stars were found to display very broad blueshifted resonance lines of highly ionized elements in this spectral range. These resonance lines originate from a hot and fast stellar line-driven wind which is very typical for supergiants in this temperature and luminosity range.
Another peculiar property of these stars was discovered in the near-infrared, in which these objects possess a pronounced excess emission pointing to hot circumstellar dust [11,12,13,14,15,16]. This dust was proposed to be most likely produced within the slow and cool component and to possibly populate a ring or disk-like region at far distances from the luminous central objects [15].
In the HR diagram, these objects are all found beyond the main-sequence and with luminosities spreading from about log L / L 4 to about log L / L 6, implying that they are all evolved, massive stars. This luminosity range was determined from the sample residing in the Magellanic Clouds (MCs), for which the luminosity determination is unquestionable, due to the low extinction towards the MCs and their well constraint distances. The classification of Galactic objects as supergiants bears much higher uncertainties due to their often poorly constrained distances, hence luminosities. We come back to this issue in Section 4.4.
The position of the MC sample in the HR diagram is shown in Figure 1 for the values of luminosity and effective temperature listed in Table 1. The stellar parameters (effective temperature T eff , visual magnitude V, and color excess E(B-V)) of the sample have been taken from the references listed in the last column of Table 1. For the calculations of the luminosities, distance moduli of 18.5 and 18.9 mag, respectively, for the Large and Small Magellanic Clouds have been utilized (see the review paper by Humphreys, this volume) along with bolometric corrections from [17].
The presence of dust around an early-type (typically of spectral type B) supergiant, along with the often pure emission-line spectra with numerous forbidden lines predominantly of [Fe ii] and [O i] finally resulted in the designation of these objects as B[e] supergiants (B[e]SGs)1.

2.1. General Aspects of B[e]SG Stars’ Disks

There is compelling evidence that B[e]SGs are surrounded by gaseous and dusty disks. The simultaneous presence of a hot and fast polar wind traced in the UV, and the cool and slow equatorial wind traced at optical wavelengths led to the assignment of a so-called hybrid or two-component wind model [15]. For this two-component wind, a density contrast between the equatorial and polar components of 100–1000 was proposed, meaning that the equatorial wind might be assigned the character of an outflowing disk [23].
The degree of non-sphericity of the envelopes and the latitude dependence of the wind density, respectively, are pursued by the measured net intrinsic polarization [30,31] and from spectropolarimetric observations [32,33]. The often high degree of intrinsic polarization support the idea of a combination of Thomson scattering by free electrons and Mie scattering by dust in a circumstellar disk [34].
If the disks of B[e]SGs are supposed to form from a high-density equatorial stellar outflow, there should be a transition zone between the atomic gas and the location of the dust, in which molecules can form in substantial amounts, because the high gas density can shield the material from the direct irradiation with dissociating UV photons coming from the hot luminous star. In fact, molecular emission, in particular of the first-overtone bands of carbon monoxide (CO), has been detected in the K-band spectra of a number of B[e]SGs in the Galaxy and the MCs (e.g., [21,35,36,37,38,39,40,41,42,43,44], see Table 2). To produce the characteristic observed emission spectra with several individual band heads, temperatures of the CO gas higher than ∼2000 K are required. These temperatures are in excess of the dust sublimation temperature, which is on the order of ∼1500 K, placing the CO emitting region closer to the star than the dust.
Additional hot molecular emission from silicon oxide (SiO) has been identified in four Galactic B[e]SGs [45], and a feature arising in the optical spectrum, which has been tentatively identified as emission from titanium oxide (TiO), was reported from six MC B[e]SGs [23,43,44,46]. However, to date, no systematic surveys for molecular emission has been performed, so that these numbers are not representative for the existence or absence of molecules in the environments of B[e]SGs. For instance, SiO emission has not been searched for yet in any of the MC B[e]SGs, and only those Galactic B[e]SGs with the most intense CO band emission have been observed in the wavelength range of the first-overtone band of SiO arising in the L-band. Hence, one might expect to find molecular emission from SiO in many more objects, but also emission from other yet undiscovered molecules that might form in the environments of B[e]SGs. What is interesting though is the fact that all MC stars displaying TiO emission also have CO emission, whereas the opposite does not hold. No detection of TiO from Galactic B[e]SGs has been reported so far.
Finally, the power of optical interferometry operating at near- and mid-infrared wavelengths should be mentioned when talking about the disks of B[e]SGs. Based on this technique, the disks of the closest and infrared brightest Galactic objects could be spatially resolved, providing precise measurements of the disk inclinations, disk sizes, and the distances of the emitting material (dust, CO gas, and ionized gas traced by the Br γ emission) from the central star (see [38,47,48,49,50,51,52]).

2.2. Disk Dynamics and Structure

Determination of the kinematics within dense circumstellar environments requires the use of reliable tracers. High-resolution near-infrared spectroscopic observations have revealed that the band heads of the CO emission from B[e]SGs typically display a characteristic shape, consisting of a blue-shifted shoulder and a red-shifted maximum. For the generation of such a band head profile, the individual CO rotation-vibration lines, superimposing within the region of the band head, must display double-peaked profiles (see Figure 2). Such line profiles can originate either from a circumstellar ring of gas expanding with constant velocity (constant outflow), or from rotational motion of a ring of gas around the central object. To discriminate between the two scenarios, complementary tracers are needed.
The SiO band emission seen in four Galactic B[e]SGs displays a similar shape of the band heads. Detailed modeling revealed that in each object the SiO bands required a slightly lower value of the velocity [45] than the CO bands. The SiO molecule is less stable than CO, meaning that it can form and persist only at lower temperatures. This fact naturally places the region where SiO molecules are expected to form, and hence the SiO band emitting region, at slower orbital velocities and greater distances from the central object.
As CO is the most stable molecule, its formation and emission region marks the inner edge of the molecular disk. Closer to the star, tracers for the kinematics need to be found from line emission of the atomic gas. Here, the lines from forbidden transitions are most suitable, because their emission is optically thin, so that their profile shapes contain the full velocity information of their formation region [56,57]. Of particular interest are hereby the [O i] lines, because they are one of the defining characteristics of the B[e] phenomenon and hence observed in all B[e]SGs. The ionization potential of O i is about the same as the one for H i, which means that within the [O i] line forming regions, hydrogen should be basically neutral as well, restricting the formation region of the [O i] line emission to the neutral regions within the circumstellar disk. While recombination in the equatorial region close to the star might be achieved, e.g., with the model of a latitude dependent wind [70,71,72], the requirement of a hydrogen neutral environment severely limits the number of free electrons that will be available to collisionally excite the levels within O i from which the forbidden transitions emerge. Consequently, the [O i] lines arise in regions with high total density, but low electron density.
The profiles of the [O i] lines often display double-peaks, in line with their formation in the disk. Typically, the [O i] λ 5577 line, which arises from a higher level than the λ λ 6300,6364 lines, is broader, indicating spatially distinct formation regions of the emissions, with the [O i] λ 5577 line being formed at higher velocities and higher densities and hence closer to the star than the other two lines.
With the identification of the lines of [Ca ii] λ λ 7291,7324 in the spectra of numerous B[e]SGs, a further highly valuable tracer for the disk kinematics has been found. These lines typically display double-peaked profiles as well, with velocities comparable to or even greater than the one traced by the [O i] λ 5577 line [53,57,58]. This implies that they form in the same region, or at least very close to each other, which is in agreement with their comparably high critical density. Since the [O i] λ 5577 line is not always detectable, the [Ca ii] lines thus provide a suitable, complementary benchmark for the dynamics within the disks of B[e]SGs.
In summary, the optical and near-infrared spectra provide emission features from several species, which are suitable to pin down the kinematics within the disks of B[e]SGs at various distances from the star, and Table 2 includes the information on the detection of the individual tracers in the MC sample. Based on the physical constraints outlined above, the logical order of the appearance of the divers tracers from inside out would be: [Ca ii], [O i], CO bands and SiO bands. The velocity information carried by these species thereby implies a decrease with increasing distance from the star. While an equatorial, outwards decelerating outflow might be able to explain some of the observed line profiles [56], the velocity patterns seem to be in better agreement with (quasi-)Keplerian rotation. In this respect, it is interesting to note that Keplerian rotation has been made directly discernible by means of spectro-interferometric observations. The rotational motion of the CO gas has been derived based on the differential phase spectrum [38,52], and the rotational motion of the ionized gas based on the spatially resolved Br γ emission [49].
While, in general, the rotational motion of the material within the circumstellar disks of B[e]SGs seems now to be well established, possibly in connection with a (very) slow outflow component [57], recent investigations of the spatial distribution of the circumstellar gas revealed that it is more likely accumulated in multiple rings, partial rings, and possible spiral arm-like structures rather than in a smooth disk [43,44,58]. These rings might result from multiple mass ejection phases caused by (pulsational) instabilities acting in the outer layers of these luminous objects (e.g., [73,74,75]), or from binary interaction in close systems, as seems to be the case for some of the Galactic objects [58], in which the rings are circumbinary rather than circumstellar. Other disk-forming mechanisms that have been proposed in the literature over the years include equatorial mass-loss from a critically rotating star [76,77], the rotationally induced bi-stability mechanism [78], the slow-wind solution [79], and the combination of the latter two [80]. For an overview including a detailed description of the various models and their limitations, see [81].
The circumstellar material of many MC objects appears durable. This is evidenced by their emission features and their infrared photometry that both display no considerable variability over several decades, in combination with chemically processed dust displaying emission from crystalline silicates [82]. It is tempting to imagine that in such an environment even minor bodies might have formed from the long-lived disk material, creating gaps within the disk in radial direction and hence leading to the formation of the presumed ring structures [43]. These minor bodies or possible planets can also stabilize the neighboring rings, in analogy to the shepherd moons in planetary systems. However, thus far, there is insufficient observational evidence that might support the validity of such a scenario.

2.3. Current Evolutionary State of B[e]SGs

The formation mechanism of the observed gaseous and dusty rings or disk-like structures around B[e]SGs is certainly one of the most important yet unsolved issues. Equally important questions arise: What is the evolutionary phase of B[e]SGs? What is their evolutionary connection to other evolved massive stars? Does such a connection exist at all? While the question on the relation between B[e]SGs and other evolved objects is beyond the scope of this review, we briefly elucidate the current knowledge about the evolutionary status of B[e]SGs. Considering the MC sample, it is obvious from Figure 1 that all objects have evolved off the main sequence. Whether this occurred only recently, or whether B[e]SGs might be on a blue loop or blueward evolution after having passed through the turning point on the cool edge of their track, is still an open issue, in particular, since we lack clear methods for age determinations of these emission-line objects, which only very rarely are detected in clusters2.
In this regard, the detection of clear signs of the 13 C isotope in the form of 13 CO band emission from a number of MC B[e]SGs ([41,86], see Table 2) was one major step forward. The appearance of these bands has been predicted based on theoretical model computations for a variation of the carbon isotope ratio 12 C/ 13 C [87]. As surface abundance calculations have shown, this ratio will drop during the evolution of massive stars from an initial, interstellar value of ∼90 down to values <5, depending on the initial mass of the star and its initial rotation speed. The surface material enriched in 13 C is transported via winds to the environments, where it will cool and condense into 13 CO molecules, whose emission can be observed in the K-band, together with the emission from the main isotope, 12 CO (see Figure 3). Hence, the detected amount of 13 CO is a measure for the stellar surface enrichment in 13 C at the time the material, which is currently traced in the molecular emission, has been released from the stellar surface.
From the MC sample of 15 objects, seven have been found to display CO band emission, and all of them display clear indication of enrichment in 13 C (see Table 2). Interestingly, all these objects with CO emission cluster in the same region of the HR diagram, as indicated by the dotted black square in Figure 1, i.e., in the luminosity range log L / L = 5.0–5.8. None of the three most luminous stars (S 22, S 111, and S 127) or of the four low-luminosity objects (S 23, S 59, S 93, and S 137) displays clear signs of CO emission. One outlier in the luminosity domain occupied by the CO emitting B[e]SGs is the star S 89, which also has no detectable CO band emission [41].
The absence of measurable CO band emission might have different reasons. Either the intensity of the emission is too low to be detectable against the strong near-IR continuum3, or the density of the molecular gas might be very high, resulting in optically thick emission, which no longer has a characteristic band head structure. Another possibility would be that the CO emission from these stars might have variable CO band emission and they have thus far always been observed in phases of no emission. In this context, it is interesting to refer to the SMC object LHA 115-S 65, in which CO band emission suddenly occurred, while observations taken about nine months earlier did not detect any molecular features [40]. Alternatively, since we now know that the material is most probably concentrated in rings, the conditions within the circumstellar environment in terms of density and temperature might not be favorable for the excitation of the first-overtone bands. For those stars, observations in the spectral region of the fundamental bands might therefore be a possibility to search for cooler CO gas.
The measured 12 C/ 13 C isotope ratios of the MC B[e]SGs are all very similar, spreading from 9 to 20. This might point towards a similar formation history of the circumstellar material, i.e., a similar phase in the evolution (considering they are single stars or at least unaffected by a possible companion) when the enriched material was ejected. Considering that stars are typically born with some intrinsic rotation velocity, rotational mixing in combination with enhanced mass-loss may drive the enrichment of the stellar surface with 13 C already in early stages of the evolution of massive stars. This can be seen in Figure 4, where the evolutionary tracks of a 32 M star with solar metallicity [88] and for a variety of initial rotation velocities are shown. The covered rotation speeds spread from v / v crit = 0 to v / v crit = 0.4 , which correspond to values of Ω / Ω crit from 0 to 0.568. The interpolation of the tracks has been performed with the SCYCLIST tool4 provided by the Geneva group.
The color coding along the tracks refers to the values of the 12 C/ 13 C isotope ratio on the stellar surface. Figure 4 also includes the positions of the seven MC B[e]SGs with known values of the 12 CO/ 13 CO isotope ratios. Their colors correspond to the same color coding as the evolutionary tracks. Obviously, the observed ratios for the sample stars might be reached either along or after the main-sequence evolution for stars rotating initially with rates Ω / Ω crit 0.3 . However, they might also be reached during or after the red supergiant stage for stars rotating initially with rates smaller than Ω / Ω crit 0.3 . As we do not know the initial rotation speeds of the progenitor stars of these B[e]SGs, the measured values of the 12 CO/ 13 CO isotope ratio alone cannot solve the issue with the current evolutionary state of the objects.
If B[e]SGs represent a specific phase in the evolution of massive stars, then these objects should also exist in other environments with high content of massive stars. Searching for representatives of B[e]SGs in other galaxies and studying their properties and number statistics at various metallicities might help to unveil their disk/ring formation mechanism, to pin down their evolutionary phase (pre- versus post-RSG), and to set constraints on the evolution of massive stars in general.

3. Identification of B[e] Supergiants in the Local Universe

Identifying and classifying B[e]SGs is a tedious job, whether in the Milky Way, where we face large amounts of foreground extinction and the issue with the often unknown distances, or in other galaxies, where we have strong contamination with foreground sources, often crowded regions, and the faintness of the objects. While the first B[e]SGs have been found rather accidentally, nowadays dedicated surveys can make use of the established classification criteria. As mentioned in Section 2, there are basically four characteristics a star should fulfill to be classified as B[e]SGs [18,25]. It should display:
  • A spectral-type B (with extensions to late-O and early-A types), as evidenced from the hot underlying continuum or from photospheric absorption features5, and a luminosity higher than log L / L 4 .
  • Very intense Balmer lines dominating the optical spectrum with an equivalent width of H α reaching up to 1000 Å.
  • A spectrum indicating the hybrid character of the environment, consisting of a hot, fast line-driven wind coexisting with a cool, slow component from which the forbidden emission lines from neutral and low-ionized metals originate ([O i], [Fe ii]).
  • Strong near- and mid-infrared excess emission, indicative of hot circumstellar dust.
Despite these defining criteria, the identification of extragalactic B[e]SGs is not as straightforward, because suitable candidates need first to be found based on other means. These candidates can then be further investigated to search for these, mostly spectroscopic, characteristics.
A suitable approach is to search for B[e]SG candidates among the luminous, blue objects identified in imaging surveys that have been performed for several galaxies over the past ∼30 years. For instance, the early photographic and photometric surveys of M31 [89,90] and M33 [91] revealed (amongst many other objects) the most luminous hot stars and the brightest blue supergiants, which could then be studied spectroscopically to obtain indications for their possible nature (e.g., [92]). A milestone for the identification of evolved massive stars was certainly the Local Group Galaxies Survey (LGGS) project [93,94], which resulted in the discovery of numerous putative emission-line stars in M31, M33, and seven more dwarf galaxies. Spectroscopic follow-ups were used to sort out H ii regions, and to match the remaining objects with the various known categories of evolved massive stars. A major result of this survey was the identification of numerous objects that were dubbed as luminous blue variable (LBV) candidates [6,95], based on the appearance of their blue emission-line or P Cygni-type spectra that resemble confirmed LBVs in quiescence. Since the blue optical spectra of LBVs in their quiescence state display a number of common characteristics with B[e]SGs [95,96,97], it was expected that this sample contains a number of B[e]SGs.
Surprisingly, when analyzed in more detail [97,98,99], this bunch of newly identified LBV candidates in M31 and M33 turned out to be a mixed bag containing not only B[e]SGs candidates, but also so-called Fe ii emission stars (with neither [O i] nor [Fe ii] emission and lacking warm dust), and warm hypergiants (with lots of dust, possible [O i] and/or [Fe ii] but of spectral type A–F), with only a few objects left to be considered as LBV candidates (with no [O i] emission and lacking hot dust).
As both LBVs and B[e]SGs are luminous blue supergiants, they share the same optical colors. Hence, one step to distinguish these two groups of objects is to inspect their location in infrared color–color diagrams (e.g., [16,20,41,97,99]). The hot (∼1000 K) circumstellar dust of B[e]SGs results in significantly increased near-IR emission. On the other hand, LBVs can be associated to cold, dusty environments such as the circumstellar shells recently discovered around many LBVs and LBV candidates with the Spitzer Space Telescope at 24 μ m ( e.g., [100,101]). The separation of B[e]SGs from quiescent LBVs, based on their diverse IR properties, is demonstrated in Figure 5 for the known samples of MC objects, limiting to the confirmed and generally accepted LBVs in the LMC [102] and including one confirmed object from the SMC (R40, [103]). Shown are two different color–color diagrams (J–H versus H–K and W1–W2 versus W2–W4). The IR colors of the objects are listed in Table 3. They result from the JHK-band magnitudes obtained from the 2MASS point source catalog6 [104], and from the mid-IR magnitudes (W1, W2, W4) collected with the Wide-field Infrared Survey Explorer7 (WISE [105]). From the many possibilities of near- and mid-IR color–color diagrams, these two show the clearest separation between the two groups of objects.
Another clear distinctive feature between B[e]SGs and LBVs is the S Dor cycle of the latter, while B[e]SGs are typically not undergoing this type of variability. However, to identify such S Dor excursions of the stars within the HR diagram is a time-consuming (though important) task, because it requires regular monitoring of the whole sample.
In addition, dedicated spectroscopic observations are required to search for the characteristic forbidden emission lines of [O i] and possible [Ca ii] in the red portion of the optical spectra, and to search for possible molecular emission of CO in their near-IR spectra, because LBVs typically do not show these sets of forbidden lines and CO band emission8 [21,35,41].

4. A Census of B[e]Sgs

With clearly defined classification characteristics and the proper observational tools at hand, the massive star population within the local Universe can be scanned for suitable B[e]SG candidates. At the moment of writing this review, this is still an ongoing project that requires patience and sufficient telescope time at both optical and infrared facilities. Nevertheless, many new, particularly extragalactic B[e]SG star discoveries were reported in the literature within the past 20 years. The aim of this section is, therefore, to take a closer and critical look at the suggested B[e]SG candidates in order to sort out possible misclassified objects, to check what type of observations are still missing for unambiguous classification of the candidates, and to compile updated lists of confirmed B[e]SGs for the galaxies with a reported B[e]SG population. The starting points for this investigation are the Magellanic Clouds (Section 4.1), moving further out into the Local Group (Section 4.2) and beyond (Section 4.3), before we finally return to the Milky Way (Section 4.4).
The samples in each galaxy are presented in tables, which follow the same structure. The objects are listed under a homogeneous SIMBAD identifier (if possible) in Column 1, reference(s) for the B[e]SG classification of the stars follow in Column 2. Where available, E(B–V) values and their references are provide in Columns 3 and 4, and the four colors (J–H, H–K, W1–W2, and W2–W4) are given along with their errors in the last four columns. The tables are furthermore organized such that in the top part appear the confirmed B[e]SGs. These are stars that fulfill all classification criteria. In the middle part of each table stars with uncertain or controversial classification are listed with their names in parentheses. These are objects that lack one or more of the classification criteria due to incomplete observational datasets. Objects for which different research teams find controversial results such that clarification is needed are also included here. In the bottom of each table, erroneously classified objects are gathered with their names in italic and within parentheses. These are stars for which observational evidence (e.g., a specific color) excludes them from belonging to the class of B[e]SGs.

4.1. Magellanic Clouds

As mentioned in Section 2, the “classical” sample of B[e]SGs resides within the Magellanic Clouds. The first such object, for which the hybrid character was reported, was the LMC star RMC 126 (LHA 120-S 127 [15]), and soon after followed the identification of ten more B[e]SGs in the LMC and four in the SMC ([16,20,22,23,24,109], see Table 1) based on a dedicated search for similar objects. Since then, a few more stars have been suggested as B[e]SGs candidates. These are presented and discussed in the following. The classical sample of B[e]SGs in the MCs, which fulfill all classification criteria, is listed in Table 1 above, with their IR colors provided in Table 3.

4.1.1. Large Magellanic Cloud

New B[e]SG candidates have been found either by dedicated searches, e.g., from cross-matching catalogs of emission-line stars with near-IR catalogs (e.g., [110]), or more serendipitously as a by-product of deep spectroscopic surveys of specific regions, such as the VLT-FLAMES Tarantula Survey (VFTS [111,112,113]) that was devoted to the 30 Doradus starburst region. In addition, surveys for other purposes, such as the search for post-asymptotic giant branch stars [114], resulted in new B[e]SG candidates9. Seven new B[e]SG objects have been proposed in total, of which only two fulfill the criteria for B[e]SGs, two are considered candidates, and three appear to be misclassified. All seven stars are listed in Table 4. Their locations in the two color–color diagrams are shown in Figure 6 in comparison with the confirmed B[e]SGs and LBVs from Table 3.
A sample of confirmed MC late-type stars and supergiants [115] is included in these color–color diagrams. These serve as reference for objects that might have a late-type companion. The outliers of the late-type stars, especially in the WISE diagram, are objects with high mass-loss.
A sample of Galactic Herbig AeBe (HAeBe) stars is also shown [116]. Only stars with known extinction values and solid magnitudes in all four bands were selected (rejecting objects with reported contamination). As some of these pre-main sequence objects suffer from very high extinction ( A V > 5 mag), their colors were corrected using an R V -dependent extinction law [117] with R V = 5.0 , which has been found to be reasonable for HAeBe stars [116]. These pre-main sequence stars were included to check for possible misclassification of objects that have a proposed luminosity ranging around the lower limit for B[e]SGs, because this luminosity range is shared by the most massive HAeBes. In the near-IR diagram, the HAeBes populate a stripe that appears to be parallel and seems to connect seamlessly to the region occupied by the classical B[e]SGs. In the WISE diagram, the HAeBes also seem to populate a stripe adjacent to the B[e]SG domain.
In the following, the reasons for classification of the new LMC objects as either confirmed or candidate, or for rejecting them as B[e]SGs are briefly presented.
LHA 120-S 165
This object was first listed as a candidate young stellar object [120], but was later classified as possible B[e]SG, based on its optical spectrum displaying all characteristic emission features (SSTISAGEMC J052747.62-714852.8 [114]). Its optical and infrared brightness together with its position in both color–color diagrams support this classification.
ARDB 54
Recent analysis of ARDB 54 revealed that it belongs to the (thus far only few) A[e]SGs, being the first of its kind in the LMC [54]. Its position in the near-IR diagram supports this classification, although the object is displaced from the region of classical B[e]SGs in the WISE diagram, where it is located closer to the LBV region. Its luminosity of log L / L 4.4 [54] is too low to be considered as LBV candidate, and a bit too high to be considered as HAeBe star. From the latter, ARDB 54 is also offset in both color–color diagrams, so that a classification as A[e]SG seems to be the most reasonable, despite its exposed location in the WISE diagram, whose cause should be examined more closely.
(VFTS 1003)
This star was found from the VLT-FLAMES Tarantula Survey [111]. In high angular-resolution near-IR images, it appears as a single, isolated object [121]. The star’s blue emission-line spectrum resembles closely the one of the Galactic B[e]SG GG Car. VFTS 1003 was suggested to be either a Herbig B[e] star or a B[e] supergiant [111]. From its position in the near-IR diagram, a supergiant classification seems more likely. However, the lack of WISE photometry allows assigning VFTS 1003 only a candidate status. In addition, for a definite B[e] classification, red optical spectra are needed, because the optical spectra reported in the literature do not cover the region of the [O i] lines.
(VFTS 822)
This late B-type star [113] is another object that was identified in the VLT-FLAMES Tarantula Survey [112] based on its blue emission-line spectrum. As with VFTS 1003, a red spectrum is needed to check for the presence of [O i] emission. Similar to that star, VFTS 822 has been proposed as possible Herbig B[e] pre-main sequence candidate. It displays a UV excess typical for pre-main sequence stars, but its luminosity of log L / L 4 is not conclusive and leaves as well room for an interpretation as evolved star. In the near-IR diagram, VFTS 822 appears within the B[e]SG domain with a clear separation from the region hosting HAeBe stars, but from the WISE diagram the star is located at the border region with the HAeBes.
(VFTS 698)
This is the third object identified within in the VLT-FLAMES Tarantula Survey and suggested as B[e]SG [119]. It also lacks a red optical spectrum to ascertain the presence of [O i] emission in order to be considered a B[e] star. Its spectral variability and photometric light curve unveiled that the object is most likely an interacting binary consisting possibly of an early B-type star and a veiled more massive companion. Its IR colors place it in both diagrams into the region occupied by HAeBe stars, but the luminosity estimates for both stars with log L / L 5 and 5.3 are too high for a pre-main sequence classification. Correcting for the extinction towards VFTS 698 would shift the object closer to the LBV domain. In the WISE diagram, the object appears particularly far off from the location of the classical B[e]SGs. Hence, this object needs further investigations for a proper classification.
([L72] LH 85-10)
Searching for LBV candidates in OB associations in the LMC, the object number 10, within the association LH 85, was found to be a luminous emission-line star. Due to the similarity of its blue spectrum with other B[e]SGs, it has been suggested as a new member of that group [96]. To date, no information about the presence of [O i] emission from that object is available. Moreover, its spectral energy distribution does not display the characteristic near-IR excess emission of B[e]SGs questioning the validity of this classification [108]. The star’s position in the near-IR diagram coincides with the region populated by LBVs, supporting the erroneous classification. No WISE photometry is available for this object.
(NOMAD1 0181-0125572)
This star appears neither in the 2MASS nor in the WISE catalog, although it was reported to have 2MASS photometry [118]. From the coordinates of the source labeled NOMAD1 0181-0125572 by Miroshnichenko et al. [110] it is obvious that it was confused with the object LHA 120-S 165. The star with SIMBAD identifier NOMAD1 0181-0125572 is not a B[e]SG.

4.1.2. Small Magellanic Cloud

In the SMC, a total of six new B[e]SGs has been reported. Five of them were discovered as by-products from the spectroscopic survey of the hot, luminous stars in the SMC (2dFS [122]), from the Runaways and Isolated O Star Spectroscopic Survey of the SMC (RIOTS4 [123]), and from the SMC photometric catalog [124]. One more object was serendipitously detected [125]. From a critical inspection of the properties of these six stars, only one object appears to fulfill all required criteria, one object appears as very promising candidate that lacks only some complementary information for unambiguous classification, whereas the remaining four stars are considered as misclassified. All objects are presented in the following, their IR colors are provided in Table 5, and their positions within the two color–color diagrams are included in Figure 6.
[MA93] 1116 = NGC 346:KWBBe 200
The star is one of the few objects residing in a cluster, the SMC cluster NGC 346. Due to its H α emission, it was first classified as a compact H ii region [126], then as a Be star based on its optical photometry [127], and in the following as B[e]SG based on its optical appearance and near-IR excess emission [125]. In the mid-IR, [MA93] 1116 displays silicate emission and strong PAH bands, features often seen in HAeBe stars (e.g., [128,129]). Additional cold dust is surrounding the object as is implied by its detection at 24 μ m with Spitzer/MIPS. These characteristics led to the suggestion that [MA93] 1116 might be an evolved young stellar object [130] or a HAeBe star [131], despite the lack of clear evidence for infall, e.g., in form of inverse P Cygni profiles. If true, its luminosity of log L / L 4.4 [54,125] would place it at the upper limit for Herbig objects, while it would get in lane with the group of less-luminous B[e]SGs in the evolved scenario. The position of [MA93] 1116 within the WISE diagram leaves room for a possible classification as HAeBe star where it falls on the edge of the region populated by HAeBe stars, whereas it appears clearly off the HAeBe region in the near-IR color–color diagram. It is hence considered as B[e]SG, and the fifth object within a cluster (the first one in the SMC).
(LHA 115-S 38 = 2dFS 1804)
This object was found from the spectroscopic survey of the hot, luminous stars in the SMC [122]. The blue spectrum displays numerous emission lines, in particular of [Fe ii], but no information about [O i] emission is available. The spectral energy distribution indicates a near-IR excess [124]. With a luminosity estimate of log L / L 4.1 the star was also considered as a post-AGB object [132], but its positions within the two color–color diagrams places the star clearly within the B[e]SG domain. As such, it is a strong candidate for another low-luminosity B[e]SG.
(LHA 115-N82 = 2dFS 2837 = LIN 495)
This star displays all spectroscopic B[e]SG characteristics [122,133] and an IR excess emission [124]. The optical spectrum was reported to be composite [122], and the detected photospheric lines display radial velocity variations, whereas the emission from the circumstellar matter appears to be stable [54]. The IR colors of LHA 115-N82 locate it clearly within the B[e]SG domains. Curiously, the V and I band light curves display a long-term brightening, which resembles LBV outbursts and is not common in B[e]SGs. On the other hand, it displays both [O i] and [Ca ii] emission, which are typically not seen in LBVs. Since the star has too low luminosity ( log L / L 3.8 ) to be an LBV (or even a B[e]SG), it was recently assigned a classification as “LBV imposter” [54]. This object clearly requires further investigations to pin down its status.
(LHA 115-S 29 = RMC 15), (LHA 115-S 46 = RMC 38), (LHA 115-S 62 = RMC 48)
The blue optical spectra of these three objects show emission-line features similar to B[e]SGs, and the luminosities derived for these objects, ranging from log L / L 4.4 to 4.8, assigns them a supergiant status [123]. However, it is currently not known whether these objects display [O i] line emission, one of the defining characters of the B[e] phenomenon. Due to the lack of a pronounced near-IR excess emission, these three stars have been proposed to be dust-poor B[e]SGs [123]. However, the presence of warm dust is another main classification criteria for a star to be considered as B[e]SG. It is not surprising that all three objects fall clearly outside the B[e]SG domains in the color–color diagrams. Instead, their positions coincide with the regions populated by LBVs, which implies that these three stars have dense winds and circumstellar ionized gas, which is exemplified by their emission-line spectra. These objects require further investigations to unveil their true nature.

4.2. Local Group Galaxies beyond the Magellanic Clouds

Moving further away, beyond the Magellanic Clouds, we may expect to find B[e]SG stars and candidates in those galaxies, in which star-formation is ongoing. For these galaxies, surveys such as the LGGS project mentioned in Section 3, but also earlier surveys (e.g., [134,135]) provide indispensable information on the population of luminous, evolved massive stars, and provide the base for systematic investigations for unambiguous classification of these objects.
To date, systematic spectroscopic studies have been performed in the two large spiral galaxies of the Local Group, M31 and M33, in which a number of B[e]SGs were found amongst the putative LBV candidates [97,99,136,137,138]. The suggested B[e]SG populations in each of these galaxies is presented in the following subsections. The samples are provided in Table 6 and Table 7, in which all objects are listed under their Local Group Galaxy Survey (LGGS) identifiers (Column 1). The properties, based on which the decision to categorize an individual star as either a candidate or a misclassified object has been made, are briefly depicted. The locations of the confirmed, candidate, and possibly misclassified B[e]SGs in the two color–color diagrams are shown in Figure 7.

4.2.1. M31

A total of 13 B[e]SGs has been proposed in M31 to date. Twelve of them resulted from optical spectroscopic observations of LBV candidates that display the typical B[e]SG characteristics [99,139]. Infrared spectroscopic observations of a small LBV candidate sample revealed so far that three display CO band emission [136,137], making their classification as B[e]SG very likely, especially since two of the CO band emission objects were also found from optical spectroscopy to be a possible B[e]SG. However, a closer look at this total sample of 13 objects, including the available information from near- and mid-IR photometric observations, reveals that only four stars can be considered as confirmed B[e]SGs. Seven objects require further clarifications, and two appear to be misclassified (see Table 6).
J004320.97+414039.6, J004415.00+420156.2, J004417.10+411928.0
These three objects fulfill all classification criteria of the confirmed B[e]SGs. Their positions in the near-IR and WISE diagrams coincide with the domain populated by the B[e]SGs, except for J004320.97+414039.6, which appears a bit off due to the uncertainties in its J and H magnitudes, which are only upper limits.
J004522.58+415034.8
The star was assigned a warm hypergiant status due to detected photospheric features pointing towards an A2Ia spectral-type [140]. As it otherwise fulfills all criteria of a B[e]SG (even displaying CO band emission [136]), it is included into the list of confirmed B[e]SGs, but keeping in mind that with its A spectral type it is actually a representative of the (though few) A[e]SGs. Recent modeling of the star’s spectral energy distribution resulted in an effective temperature estimate of 11,000 K [142], which would point towards a late-B spectral type.
(J004220.31+405123.2), (J004221.78+410013.4), (J004229.87+410551.8), (J004442.28+415823.1)
These stars display the optical characteristics of B[e]SGs [99], and their WISE colors place them within the B[e]SG domain. However, all four objects lack JHK band photometry, so that they cannot be located in the J–H versus H–K diagram. The presence of He i emission in J004221.78+410013.4 [99] contradicts the proposed effective temperature of 7200 K [142] and requires clarification.
(J004411.36+413257.2)
The star is reported to display He i, Fe ii, and [Fe ii] emission and was suggested as B[e]SG star [139]. Whether it displays [O i] emission was not discussed by these authors and is hence yet unclear, although the spectrum covers that spectral region. Its J–H color is smaller than for typical B[e]SGs (but the H magnitude is uncertain), placing the star at the lower boundary for the B[e]SGs in the color–color diagram. No WISE photometry exists. The closest IR source is more than 6 arcsec away. The object is not reported in other published spectroscopic investigations to display all B[e]SG characteristics. Instead, it was listed as Fe ii emission line star [98] and more recently as LBV candidate [142].
(J004444.52+412804.0)
This object was first proposed to be a P Cyg-type LBV candidate [95]. With the detection of [Ca ii] emission and circumstellar dust [98], and with the determination of an effective temperature of 6600 K [142], it was classified as a warm hypergiant. On the other hand, a B[e]SG classification with a central star of 15,000–20,000 K has been suggested, based on the presence of He i lines displaying P Cyg profiles and the detection of intense CO band emission [137]. This controversial classification, based on spectra taken at similar epochs, requires clarification. Infrared photometry places J004444.52+412804.0 within the region occupied by B[e]SGs in the two color–color diagrams.
(J004621.08+421308.2)
A status of a late A-type warm hypergiant has been assigned to this object based on the lack of detected He i emission [143]. In contrast to this, He i emission lines were reported by Sholukhova et al. [139], and an effective temperature of 10,000 K has been estimated from the modeling of the stars’ spectral energy distribution [142]. The position of the object in the near-IR and WISE diagrams coincides with the B[e]SG domain.
(J004043.10+410846.0)
Its optical spectrum displays all typical characteristics of a B[e]SG [99], and its WISE colors confirm the presence of warm dust, but its (though uncertain) unusually high J–H value of 1.6 at a low value of H–K fits neither to B[e]SGs nor to LBVs.
(J004057.03+405238.6)
No IR photometry is available, so that currently no statement can be made about the presence of (hot) dust. The absence of He i lines in the optical spectra along with an effective temperature of 7700 K [142] speak against a B[e]SG classification.

4.2.2. M33

In M33, the sample of putative LBV candidates [6,95] served also as a starting point for a more detailed investigation of the individual objects. Optical [97,99,141], and infrared [138] spectroscopic studies revealed so far a total of ten possible B[e]SGs. They are listed in Table 7. Combined with the available information about their infrared colors, only two objects can currently be considered as confirmed B[e]SGs, six need further clarification, and two objects appear to be misclassified.
J013333.22+303343.4, J013350.12+304126.6
Both objects display all classification characteristics of B[e]SGs. Their locations in the WISE diagram coincide with the B[e]SG domain. In the near-IR diagram they appear slightly off the B[e]SG region, shifted towards the HAeBe domain, but their high-luminosities clearly classify them as supergiants. The CO band absorption detected from J013333.22+303343.4 cannot be explained with a cool companion, but might originate from a pole-on seen jet [138]. Whether also CO band emission is present in this object, but veiled by the intense absorption component, is currently unknown.
(J013324.62+302328.4), (J013342.78+303256.3), (J013349.28+305250.2), (J013426.11+303424.7), (J013459.47+303701.9), (J013500.30+304150.9)
All six objects lack near-IR photometry, which renders it difficult to unambiguously classify them as B[e]SGs, although their mid-IR colors and their optical spectroscopic appearances support such a classification. The star J013342.78+303256.3 has even no mid-IR photometry, so that it is unclear whether it is surrounded by (warm) dust at all. There is an IR source at a distance of ∼4.5 arcsec which is considered as too far off to be identified with J013342.78+303256.3. The sources J013324.62+302328.4 and J013500.30+304150.9 were reported as intrinsically faint objects with little extinction, and were suggested as counterparts of the low-luminosity B[e]SG in the MCs [97]. However, according to the luminosity estimates for these stars, for which values of log L / L 4.8–5.0 were obtained [142], these stars fall rather onto the lower boundary of the high-luminosity B[e]SGs sample within the MCs (see Figure 1).
(J013242.26+302114.1)
The optical spectra of this object display all typical B[e]SG characteristics, but the star’s IR colors displace it clearly from the sample of confirmed B[e]SGs. It has excess emission at 8 μ m due to PAHs [99]. The JHK magnitudes suggest that J013242.26+302114.1 falls into the region of late-type stars and stars with a late-type companion, respectively, [20,144]. This classification is supported by the WISE colors, although regular late-type stars typically have slightly negative W1–W2 colors. Considering only the WISE photometry, J013242.26+302114.1 would fit to the region populated by LBVs. This objects clearly needs to be investigated in more detail for a proper classification.
(J013406.63+304147.8)
This star is also known as [HS80] B416. Despite the detected CO band emission from this object [138], a classification as B[e]SG seems not appropriate (as previously mentioned by Humphreys et al. [98,99]), because its near-IR colors show clearly the lack of warm dust and would place the object to the region populated by LBVs. In addition, no [Oi] emission is seen from J013406.63+304147.8 [98]. However, thus far, no photometric variability, typical for LBVs, is recorded [97], and the star can only be considered as a possible LBV candidate, as was previously suggested [99]. The star is found to be surrounded by an expanding ring-like nebula [141] and shows excess emission at 8 μ m due to PAHs [138]. The spectral energy distribution leaves space for a companion [98,138], and its spectral lines display radial velocity variations with a period of 16.13 d, leading to the suggestion that the system might be an interacting binary system causing mass loss in the equatorial plane [145].

4.3. Beyond the Local Group

Not much is known yet about the B[e]SG population beyond the Local Group. Most promising for dedicated searches are the nearby large spiral galaxies M81, M101, and NGC 2403, for which pioneering ground-based surveys have been conducted already in the 1980s and 1990s [146,147,148,149] and which are nowadays extended to fainter objects thanks to the capabilities of the Hubble Space Telescope (e.g., [150]). Spectroscopic follow-up investigations revealed a number of variable luminous objects [151,152,153,154,155], but only in one of these galaxies, M81, three B[e]SG candidates have been found so far [156]. They all display the typical B[e] features in their optical spectra, but without complementary information about the presence of (warm) circumstellar dust, their classification remains preliminary. These objects will certainly not remain the only of their kind, because the search for more candidates has just begun.
The B[e]SG candidates in M81 are listed in Table 8. For lack of proper SIMBAD identifiers for these objects, the table contains the star ID [156] along with the coordinates and, where available, the V band magnitudes.
In the past few years, additional surveys have been performed, using large ground-based facilities (e.g., [157]) and space telescopes (e.g., [158,159]). These surveys were aimed at revealing the luminous and variable massive star populations of other galaxies even further away. They provide an excellent basis for follow-up spectroscopic studies to classify their massive star content, so that many more LBV candidates and B[e]SGs may be found in the (near) future. In addition, the Local Group galaxies still need to be explored in more detail, in particular those galaxies that were already found to possess (even though in very small numbers) LBV candidates [95] that are awaiting their proper classifications. The upcoming era of the Extreme Large Telescope (ELT) promises to become particularly fruitful. The next generation of high-sensitivity instruments combined with the large collecting area of the telescope will facilitate ground-based spectroscopic observations of faint objects with very high spatial resolution.

4.4. Galactic Objects

Finally, we return to our own Galaxy. Searching for B[e]SG stars in the Milky Way is a difficult task. Though many B[e] stars are known, the assignment of a supergiant status is significantly hampered due to highly uncertain distances, hence luminosities. The situation will hopefully change with the final data release from the GAIA mission, from which one hopes for accurate parallax measurements. However, for now, the luminosities of the objects are subject to large uncertainties, so that only objects with a reported luminosity of at least log L / L 5 are considered as serious B[e]SG candidates.
The lower luminosity boundary of log L / L 4.0 for an evolved star to be assigned a supergiant status is a further hindrance in the classification of objects as B[e]SGs, because this luminosity domain is shared with the massive pre-main sequence (HAeBe) stars. The latter have emission-line spectra with numerous forbidden emission lines from [Fe ii] and [O i] similar to the B[e]SGs, and the stars are surrounded by significant amounts of circumstellar dust within their massive accretion disks causing considerable IR excess emission, just as the B[e]SGs. Hence, it is not surprising that confusion exists about the proper classification for a number of objects within this luminosity domain of 4.0 < log L / L < 4.5 , and that Galactic B[e]SG candidates also appear as candidates in catalogs of HAeBe stars (see, e.g., [160]). In the absence of clear indications for infall of material, which is a typical characteristic of pre-main sequence stars, alternative discriminators for the classification of such objects are needed.
A reasonable approach to this is to search for 13 CO emission from the circumstellar environments of the uncertain candidates. Many HAeBe stars have been reported to display CO band emission from their massive accretion disks (e.g., [161,162,163,164,165]). As these disks form from material provided by the interstellar medium in which the 12 C/ 13 C isotope abundance ratio has typically a value of about 90 [88], these pre-main sequence disks can clearly be distinguished from the disks around evolved massive stars, which should be enriched in 13 C and hence give rise to clearly measurable emission in 13 CO. K-band spectra of these objects, covering the first-overtone bands of both 12 CO and 13 CO (see Section 2.3 and Figure 3), are thus key for a proper discrimination between a young (pre-main sequence) and an evolved status.
From the currently proposed 15 Galactic B[e]SGs listed in Table 2, nine have been reported to display CO band emission. However, thus far, only four of them have been observed in the region around the 13 CO bands. The spectra of all four stars have been found to display clear signatures of 13 CO emission, and model results revealed that the environments of all four objects are clearly enriched in 13 C. Two of these objects were already known to be supergiants based on their confirmed high luminosities: the stars GG Car [41,42] and Hen 2-398 [41]. For the other two, which so far have also been considered as HAeBe candidates (see Table 9), the detection of chemically processed material can hence be regarded as the ultimate proof of their evolved, supergiant nature. These are the objects MWC 137 [59] and MWC 349 [62]. These results are very promising and encouraging, and they demonstrate that the 13 CO molecular emission provides a solid tool to unambiguously classify a star as either a pre-main sequence or an evolved object. Clearly, more observational effort needs to be undertaken to search also for the signatures of 13 CO in the spectra of the remaining objects.
When collecting the IR magnitudes of the Galactic sample, it turned out that only the near-IR measurements are reliable, whereas the WISE measurements for all objects have been flagged as being contaminated by neighboring objects. The latter are hence useless for classification purposes, and one can currently only rely on the JHK-band magnitudes. The list of objects, their observed colors, and literature values of their color excess are listed in Table 9. The relatively high values of the color excess requires correction for extinction before placing the objects to the near-IR diagram. Corrections have been performed with the galactic extinction curve using an R V value of 3.1 [117]. The extinction corrected colors are included in Table 9, and the positions of the objects are shown in Figure 8 separately for the confirmed (Figure 8, top) and candidate objects (Figure 8, bottom).
The separation of confirmed from candidate B[e]SGs is based on two characteristics: (i) stars with detected enrichment in 13 CO of their circumstellar environments are considered as confirmed; and (ii) stars with reported (by more than one research team) luminosity values of log L / L 5.0 . Objects with lower luminosities 4.0 < log L / L < 5.0 are assigned a candidate status. Based on these criteria, the Galactic sample splits into nine confirmed B[e]SGs and six candidates (see Table 9).
MWC 137, MWC 349, GG Car, Hen 3-298
These four objects are considered as confirmed B[e]SGs based on the detected enrichment of their circumstellar disk material with 13 CO (see Table 2). They all fall into the region of the confirmed B[e]SGs in the near-IR diagram, regardless of the large error bar for MWC 349.
CPD-52 9243, HD 327083, MWC 300
All three stars fulfill the high luminosity criterion. The near-IR colors of CPD-52 9243 and HD 327083 place these two objects within the B[e]SG domain. MWC 300 appears regularly in studies of HAeBe stars. Its near-IR colors locate this star close to the B[e]SGs but far away from the HAeBe region, making a pre-main sequence nature of this object rather unlikely. Its relatively high color values might be influenced by a possible companion [51,172].
AS 381, CPD-57 2874
These two objects are also known to have high luminosities, but they reside slightly outside the classical B[e]SG domain in the near-IR diagram. AS 381 is a reported binary [64,65] consisting of a luminous B[e]SG and a K-type companion, which seems to (significantly) contribute to the total near-IR flux, hence altering the colors of the B[e]SG. The near-IR colors of CPD-57 2874 place it closer to the LBVs rather than to the B[e]SGs, although its H–K color is subject to large uncertainty. Its pronounced emission in CO, and in the [O i] and [Ca ii] forbidden lines [58] speak against an LBV classification.
(Hen 3-938), (MWC 342), (Hen 3-303), (CD-42 11721)
The rather low luminosities of these four objects and the closeness or even coincidence of their location with the HAeBe domain clearly requires further studies for an unambiguous classification. While Hen 3-938 and MWC 342 have to our knowledge not yet been spectroscopically observed in the K-band, the other two stars showed no evidence for CO band emission [39]. This renders their classification more difficult.
(HD 87643)
The near-IR colors of HD 87643 place it to the high end of the HAeBe regime. However, these colors have large errors and require refinement. Studies based on long-baseline interferometry revealed that this object consists of two B-type stars, and each component might be surrounded by a dusty disk [174]. Whether this object is a physical binary is currently not known.
(HD 62623)
It appeared in the literature as the first A[e]SG [49,176] and is known to be surrounded by a detached gas and dust disk, from which also CO band emission has been detected [39,58]. It has been speculated that the gap between the star and the inner rim of the gas disk might have been cleared by a companion. However, no clear evidence of such a companion has been found yet. Its low luminosity and large errors in the near-IR photometric measurements make it challenging to unambiguously assign the star a B[e]SG status, although its position within the near-IR seems to coincide more with the B[e]SG domain rather than with any other classification. This object is an ideal candidate to clarify its nature based on dedicated K-band observations to analyze the 13 CO content within its circumstellar disk.

5. Discussion and Conclusions

B[e]SGs form a special class of evolved massive stars and are thought to represent a short-lived transition phase either in their red-ward, post-main sequence evolution, or in their blue-ward post-RSG evolution. The total number of currently known B[e]SGs is low, supporting the idea of a short transition phase. However, in which direction the stars evolve, and whether all B[e]SGs evolve in the same direction, is still an open issue. For the objects in M31 and M33, it has been argued that the B[e]SGs are more isolated than LBVs and hardly found in stellar associations, so that a post-RSG (or post-yellow supergiant) evolution was proposed to be more likely [142]. This assessment was based on the available numbers of putative B[e]SGs in these two galaxies at that time. However, after revision of the two samples (Table 6 and Table 7), two of the four confirmed B[e]SGs in M31 and both confirmed B[e]SGs in M33 are associated with stellar groups, questioning the conclusion that B[e]SGs are isolated and thus post-RSGs.
The best age indicator for B[e]SGs we have to date is their surface abundance enrichment in 13 C, as discussed in Section 2.3. If B[e]SGs were post-RSGs, their progenitors would all have started with a (very) low rotation speed. While such a scenario cannot be excluded, it may not be very likely considering that stars are born on average with a rotation rate of about 40% of their critical velocity [88].
Interaction within a (close) binary system, possibly even up to a binary merger, seems to be an alternative and popular scenario (e.g., [51,177]), but the number of currently confirmed binaries amongst B[e]SGs is still rather low to give preference to the binary channel as the sole possible way for the formation of B[e]SGs. Likewise, some B[e]SGs have been suggested as suitable supernova candidates. For example, the Galactic object MWC 137 appears similar to Sher 25 [178] and SBW1 [179], which both look like the progenitor of SN1987A. In addition, the SMC object LHA 115-S 18 has been proposed to be a viable SN1987A progenitor [27]. In this respect, it is vital to resolve B[e]SG populations and to study their properties.
In this review, a census of the currently known B[e]SG population in the Milky Way and in nearby star-forming galaxies within and beyond the Local Group is presented. The proposed candidates have been undertaken a critical examination, sorted into confirmed B[e]SGs and B[e]SG candidates, and unsuitable objects have been flagged as “misclassified”10.
During these investigations, a fundamental difference has been recognized between the identification issues for objects in our Galaxy compared to those in other galaxies. Extragalactic B[e]SGs bare the risk of being confused with LBVs in quiescence, which share very similar optical spectroscopic characteristics. To separate these two classes of objects, one can make use of clearly defined classification criteria based on certain sets of emission features identified in their optical and near-IR spectra, as outlined in Section 3. In addition, inspection of the location of possible B[e]SG candidates in the IR color–color diagrams is highly advisable, because B[e]SGs and LBVs populate clearly separate domains. This fact might also be used as starting point for future investigations of extragalactic samples. However, for such future studies, infrared photometry with higher spatial resolution than what is currently provided by 2MASS and WISE is desirable to prevent from contamination with neighboring sources in densely populated regions. Moreover, precise distances, as soon provided by GAIA, will help to separate foreground stars in the directions to other galaxies that might have been misclassified as luminous extragalactic stars.
In the Milky Way, an additional complication occurs due to the often uncertain luminosity estimates, and the overlap of low-luminosity B[e]SGs with the most luminous massive pre-main sequence objects (HAeBe). Here, special care needs to be taken, especially since both classes of objects occupy adjacent regions in the near-IR color–color diagram with a probable overlap. Without additional distinctive features for such low-luminosity, borderline B[e]SG candidates, their real nature remains elusive. One complementary classification criteria that was discussed, is provided by the enrichment of the circumstellar material of evolved objects with processed material that has been released from the stellar surface, as opposed to the non-processed material with interstellar abundance patterns found around HAeBes. The most ideal element to search for is 13 C, which is bound in 13 CO molecules in the circumstellar disks. Measuring the 13 CO amount with respect to 12 CO provides immediate insight into the nature of the object. The current HAeBe samples might hide such low-luminosity B[e]SG candidates, which can only be identified as such by careful and honest analysis.
The result from this census, after strict application of the classification criteria, is that we count nine confirmed and six candidate B[e]SGs in the Galaxy. Moving out to the MCs, the numbers amount to 13 (+2) in the LMC and 5 (+1) in the SMC. The situation in other members of the Local Group is not much better, where the numbers drop to four (+7) in M31 and two (+6) in M33. Even further away, only three candidates have been reported from M81. The total number of B[e]SGs found in the various galaxies are too small for statistical analyses with respect to a metallicity dependence of their number, but the comparable quantities within the Milky Way and the LMC suggest only a mild dependence of the amount of B[e]SGs on (i.e., a possible drop with decreasing) metallicity.
Further, we report that the Galactic sample of 15 B[e]SGs and candidates contains currently seven confirmed or suspected binaries (see Table 9), which is less than half of the population. In the MCs, this number is even lower, because thus far only three stars have been reported to be possible binaries, of which one, the SMC star LHA 115-S 6 (= RMC 4) has been proposed to be the remnant of a binary merger within an initially triple system [182,183]. The other two objects, the LMC star LHA 120-S 134 and the SMC object LHA 115-S 18, have been identified as optical counterparts of X-ray sources [27,29]. Nothing is known about possible binarity in the B[e]SG samples from the other galaxies, although photometric variability was seen in at least two M31 objects: the confirmed B[e]SG star J004417.10+411928.0 [137,184] and the candidate J004444.52+412804.0 [185,186]. Whether this variability is a sign of binarity or just of semi-regular variability which might be interpreted with pulsation activity such as reported from the α Cygni variables, needs to be studied in more detail.
For the sake of completeness, a special class of objects, which have not been discussed yet, should be briefly mentioned as well. These are the high-mass X-ray binaries (HMXB) with possible B[e] supergiant (candidate) companion. Some objects with an assigned B[e]SG status have been found to be too luminous in X-rays for being considered single stars. These objects have been proposed to be binary systems, in which the high energy emission is caused by either accretion onto a compact object, or by shocks in a colliding wind binary with a second massive star. Members of this group are the Galactic objects Cl* Westerlund 1 W 9 (=Wd1-9), which is considered a colliding wind system [85]; CI Cam (=MWC 84), which might be interpreted as supernova imposter [187]; and the high-mass X-ray binary (HMXB) IGR J16318-4848, in which the compact object was proposed to be a neutron star [188]. Two ultra-luminous X-ray sources (ULXs), Holmberg II X-1 and NGC 300 ULX1, the latter being also named as supernova imposter SN2010da, have also been proposed to be HMXBs including a B[e]SG [189,190,191]. Whether these objects indeed host a B[e]SG clearly needs to be investigated in more detail. However, since the behavior of these sources is considerably different from the confirmed B[e]SGs, I hesitate to include them into the census.
The presented populations represent the current knowledge of B[e]SGs and B[e]SG candidates in the closest star-forming galaxies. With the ever growing sensitivities of instruments and telescope sizes, the future in B[e]SG star research is bright, because many more candidates will be identified in even more distant galaxies and with metallicities spreading over a large range. With statistically meaningful samples, it will finally be possible to unveil the nature and fate of these fascinating objects.

Funding

This project received funding from the Grant Agency of the Czech Republic (GAČR, grant number 17-02337S). The Astronomical Institute of the Czech Academy of Sciences, Ondřejov, is supported by the project RVO:67985815.

Acknowledgments

I wish to thank the editor, Roberta Humphreys, for the invitation to write this review. In addition, I am grateful to Michalis Kourniotis for inspiring discussions on searching for extragalactic B[e]SGs, and to Dieter Nickeler and Lydia Cidale for passionate discussions about B[e]SGs as well as for their proofreading of and suggestions on the draft versions. Moreover, I thank the anonymous referees for their careful reading and suggestions on the draft version. This research made use of the NASA Astrophysics Data System (ADS) and of the SIMBAD database, operated at CDS, Strasbourg, France. This publication makes use of data products from the 2MASS, which is a joint project of the University of Massachusetts and the Infrared Processing and Analysis Center/California Institute of Technology, funded by the National Aeronautics and Space Administration and the National Science Foundation. This publication makes use of data products from the Wide-field Infrared Survey Explorer, which is a joint project of the University of California, Los Angeles, and the Jet Propulsion Laboratory/California Institute of Technology, funded by the National Aeronautics and Space Administration.

Conflicts of Interest

The author declares no conflict of interest.

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1
Note that these objects have previously been abbreviated sgB[e] [25], to separate them from other stars showing the B[e] phenomenon. We prefer the designation B[e]SG, to be in line with the naming and abbreviation of other types of supergiants such as blue supergiant (BSG) and red supergiant (RSG).
2
Currently, only four B[e]SGs are reported to be cluster members: the two LMC objects LHA 120-S 111 in the compact cluster NGC 1994 [26] and LHA 120-S 35 in SL482 [44], and the two Galactic sources MWC 137 in SH 2-266 [83] and Wd1-9 in Westerlund 1 [84,85].
3
This spectral region suffers from strong telluric contamination, which is not always easy to remove, so that especially weak CO emission features might be hidden within telluric remnants.
4
5
We would like to stress that the high-luminosity B[e]SGs barely display photospheric absorption lines, whereas the low-luminosity B[e]SGs typically do.
6
7
8
One exception to this rule is the LBV star HR Car, which occasionally showed CO band emission related to phases when the star was dimmer [107].
9
I would like to point out that from the proposed 12 newly discovered B[e] stars only one was found to be a supergiant (see Table 4). The others have been carefully inspected in collaboration with Devika Kamath, and they did not fulfill the requirements. These results are yet unpublished.
10
We would like to caution that, with insufficient knowledge of stellar properties, individual objects may easily be misclassified, as it happened in recently published catalogs [6,102,180,181], in which erroneously a number of (even confirmed) B[e]SGs are listed as LBV candidates.
Figure 1. HR diagram showing the positions of the classical MC B[e]SG sample [18]. The stellar evolutionary tracks at SMC metallicity for stars rotating initially with 40% of their critical velocity are also included (from [19]). The dotted square contains objects that display CO band emission (except for S 89, see Section 2.3). For brevity and readability, the identifiers LHA 120 and LHA 115 for objects within the LMC and SMC, respectively, have been omitted.
Figure 1. HR diagram showing the positions of the classical MC B[e]SG sample [18]. The stellar evolutionary tracks at SMC metallicity for stars rotating initially with 40% of their critical velocity are also included (from [19]). The dotted square contains objects that display CO band emission (except for S 89, see Section 2.3). For brevity and readability, the identifiers LHA 120 and LHA 115 for objects within the LMC and SMC, respectively, have been omitted.
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Figure 2. Sketch of the generation of the typical CO band head profile. (a) Spectrum around the (2-0) band head of the CO first-overtone bands for a hot gas with velocity dispersion of a few km s 1 . (b) Profile of a single line from a rotating gas ring with a velocity, projected to the line of sight, of 66 km s 1 as seen with a spectral resolution of 6 km s 1 . (c) Total synthetic CO band head spectrum resulting from the convolution of the band transitions in (a) with the profile of the ring in (b). (d) CO band head observations of the Galactic B[e]SG CPD-57 2874 [58].
Figure 2. Sketch of the generation of the typical CO band head profile. (a) Spectrum around the (2-0) band head of the CO first-overtone bands for a hot gas with velocity dispersion of a few km s 1 . (b) Profile of a single line from a rotating gas ring with a velocity, projected to the line of sight, of 66 km s 1 as seen with a spectral resolution of 6 km s 1 . (c) Total synthetic CO band head spectrum resulting from the convolution of the band transitions in (a) with the profile of the ring in (b). (d) CO band head observations of the Galactic B[e]SG CPD-57 2874 [58].
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Figure 3. Synthetic spectra of the combined emission from 12 CO and 13 CO for different values of the 12 C/ 13 C ratio. The computations have been performed for the following physical parameters: a 12 CO column density of 2 × 10 21 cm 2 , a gas temperature of 3000 K, a line-of-sight rotational velocity of 66 km s 1 , and a spectral resolution of 50 km s 1 .
Figure 3. Synthetic spectra of the combined emission from 12 CO and 13 CO for different values of the 12 C/ 13 C ratio. The computations have been performed for the following physical parameters: a 12 CO column density of 2 × 10 21 cm 2 , a gas temperature of 3000 K, a line-of-sight rotational velocity of 66 km s 1 , and a spectral resolution of 50 km s 1 .
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Figure 4. Evolution of the 12 C/ 13 C isotope ratio along the solar metallicity tracks of a star with initial mass of 32 M and initial rotation speeds v / v crit ranging from 0 to 0.4 (corresponding to Ω / Ω crit = 0.0 ; 0.1 ; 0.2 ; 0.3 ; 0.4 ; 0.5 ; 0.568 ). The individual tracks have been obtained from the interpolation tool SCYCLIST provided by the Geneva group. For clarity of the plot, we truncated the evolutionary tracks within the red supergiant regions. Included are the positions of the MC B[e]SG sample from Table 2 with known 12 C/ 13 C ratio, following the same color coding as for the tracks. The Galactic objects are excluded due to their highly uncertain luminosities. Depending on the initial rotation speed of the star, the observed ratio can be reached either in the pre-RSG (moderate rotator) or post-RSG (slow rotator) phase.
Figure 4. Evolution of the 12 C/ 13 C isotope ratio along the solar metallicity tracks of a star with initial mass of 32 M and initial rotation speeds v / v crit ranging from 0 to 0.4 (corresponding to Ω / Ω crit = 0.0 ; 0.1 ; 0.2 ; 0.3 ; 0.4 ; 0.5 ; 0.568 ). The individual tracks have been obtained from the interpolation tool SCYCLIST provided by the Geneva group. For clarity of the plot, we truncated the evolutionary tracks within the red supergiant regions. Included are the positions of the MC B[e]SG sample from Table 2 with known 12 C/ 13 C ratio, following the same color coding as for the tracks. The Galactic objects are excluded due to their highly uncertain luminosities. Depending on the initial rotation speed of the star, the observed ratio can be reached either in the pre-RSG (moderate rotator) or post-RSG (slow rotator) phase.
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Figure 5. Demonstration of the separation of the B[e]SGs from the quiescent LBVs within the near-IR (J–H versus H–K diagram (left)) and the WISE diagram (W1–W2 versus W2–W4 (right)). Shown are the positions of the classical MC B[e]SG sample and of the MC LBV sample. IR colors of the objects are provided in Table 3. The solid line represents the positions of regular supergiants with empirical colors taken from [106] for solar metallicity stars.
Figure 5. Demonstration of the separation of the B[e]SGs from the quiescent LBVs within the near-IR (J–H versus H–K diagram (left)) and the WISE diagram (W1–W2 versus W2–W4 (right)). Shown are the positions of the classical MC B[e]SG sample and of the MC LBV sample. IR colors of the objects are provided in Table 3. The solid line represents the positions of regular supergiants with empirical colors taken from [106] for solar metallicity stars.
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Figure 6. Location of the new LMC (light blue) and SMC (purple) samples with respect to those MC B[e]SGs that meet all the required classification criteria (dark blue) and LBVs (red triangles) in the near-IR (top) and the WISE diagram (bottom). Filled circles are used for confirmed B[e]SGs, filled stars for candidates, and empty circles for misclassified objects. A sample of late-type stars and supergiants in the MCs (small gray crosses, from [115]) and a sample of (dereddened, see text) Galactic HAeBe stars (black plus signs, from [116]) are also included. The arrow in each panel indicates the direction of the reddening, and their length complies with a value of A V = 3 . As the color excess is not known for all MC objects, no extinction correction has been applied. However, the MC stars have in general relatively small color excess values (see Table 4 and Table 5), which would shift them only marginally in the diagrams.
Figure 6. Location of the new LMC (light blue) and SMC (purple) samples with respect to those MC B[e]SGs that meet all the required classification criteria (dark blue) and LBVs (red triangles) in the near-IR (top) and the WISE diagram (bottom). Filled circles are used for confirmed B[e]SGs, filled stars for candidates, and empty circles for misclassified objects. A sample of late-type stars and supergiants in the MCs (small gray crosses, from [115]) and a sample of (dereddened, see text) Galactic HAeBe stars (black plus signs, from [116]) are also included. The arrow in each panel indicates the direction of the reddening, and their length complies with a value of A V = 3 . As the color excess is not known for all MC objects, no extinction correction has been applied. However, the MC stars have in general relatively small color excess values (see Table 4 and Table 5), which would shift them only marginally in the diagrams.
Galaxies 07 00083 g006
Figure 7. As Figure 6 but for the location of the M31 (light blue) and M33 (purple) samples in the near-IR (top) and the WISE diagram (bottom) based on their observed colors. Typical values for the objects’ reddening are A V 1.5 mag [142].
Figure 7. As Figure 6 but for the location of the M31 (light blue) and M33 (purple) samples in the near-IR (top) and the WISE diagram (bottom) based on their observed colors. Typical values for the objects’ reddening are A V 1.5 mag [142].
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Figure 8. Near-IR diagrams as in Figure 6, showing the locations of the Galactic confirmed B[e]SGs (top) and B[e]SG candidates (bottom). The colors of the Galactic objects have been corrected for interstellar extinction (Table 9).
Figure 8. Near-IR diagrams as in Figure 6, showing the locations of the Galactic confirmed B[e]SGs (top) and B[e]SG candidates (bottom). The colors of the Galactic objects have been corrected for interstellar extinction (Table 9).
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Table 1. Names and parameters of the established B[e]SG sample within the Magellanic Clouds.
Table 1. Names and parameters of the established B[e]SG sample within the Magellanic Clouds.
ObjectOther Common Identifierslog T eff log L/L VE(B–V)Ref.
Large Magellanic Cloud B[e]SGs
LHA 120-S 12SK −67 234.365.41 ± 0.0412.60.2–0.25[16]
LHA 120-S 22HD 34664, SK −67 644.39 ± 0.045.89 ± 0.0911.70.25–0.3[16]
LHA 120-S 35SK −66 974.34 ± 0.065.21 ± 0.1012.50.07[20]
LHA 120-S 594.14 ± 0.094.01 ± 0.1514.40.05[20]
LHA 120-S 73RMC 66, HD 2688354.065.51 ± 0.0310.60.12–0.15[13]
LHA 120-S 89RMC 82, HD 2692174.275.44 ± 0.0312.00.20[16]
LHA 120-S 93SK −68 664.00 ± 0.064.61 ± 0.1012.70.22[20]
LHA 120-S 111 aHD 2695994.196.0610.30.28[21]
LHA 120-S 127RMC 126, HD 379744.356.12 ± 0.0210.90.25[15]
LHA 120-S 134 b,cHD 38489, SK −69 2594.425.82 ± 0.0612.00.2–0.25[16]
LHA 120-S 1374.11 ± 0.104.24 ± 0.1614.00.17[20]
Small Magellanic Cloud B[e]SGs
LHA 115-S 6 bRMC 4, AzV 164.435.0213.00.07[22]
LHA 115-S 18 b,cAzV 1544.405.6013.30.4[23]
LHA 115-S 23AzV 1724.044.3113.30.03–0.1[24]
LHA 115-S 65RMC 504.235.65 ± 0.0411.60.15–0.2[16]
Note: Former designations of some of the objects as Hen S # (see, e.g., [25]) were omitted here, as these are not SIMBAD identifiers. However, LHA 120-S and LHA 115-S, respectively, and the former Hen S numbers refer to the same objects. a The star is also listed as RMC 105 in SIMBAD, but this designation should be used for a neighboring, normal B-type star in this dense cluster (see [26]). b Confirmed or suspected binary. c X-ray source [27,28,29].
Table 2. Presence of disk tracers in the optical and near-IR spectra of the Galactic and Magellanic Cloud B[e]SG samples.
Table 2. Presence of disk tracers in the optical and near-IR spectra of the Galactic and Magellanic Cloud B[e]SG samples.
Object[Ca ii][O i] aRef.CO 12 C/ 13 CRef.TiOSiORef.
Large Magellanic Cloud B[e]SGs
LHA 120-S 12yesno[53]yes20 ± 2[21,41]yes[23]
LHA 120-S 22yesyes[53]no[21,41]noTW b
LHA 120-S 35yesyes[44]yes10 ± 2[41,44]yes[44]
LHA 120-S 59noyes[54]?[41]noTW b
LHA 120-S 73yesyes[43,53]yes9 ± 1[21,41,43]yes[55]
LHA 120-S 89nonoTW bno[21,41]noTW b
LHA 120-S 93yesnoTW bno[41]noTW b
LHA 120-S 111yesyes[53]no[21]yes[23]
LHA 120-S 127yesyes[53,56]no[21,41]noTW b
LHA 120-S 134yesyes[53]yes15 ± 2[21,41]yes[23]
LHA 120-S 137noyesTW bno[41]noTW b
Small Magellanic Cloud B[e]SGs
LHA 115-S 6?yesTW byes12 ± 2[36,41]noTW b
LHA 115-S 18yesyes[53]yes20 ± 5[37,41]yes[23,46]
LHA 115-S 23 c?noTW bnoTW dnoTW b
LHA 115-S 65yesyes[53,57]yes e20 ± 5[40,41]noTW b
Galactic B[e]SGs/B[e]SG Candidates
MWC 137nono[55,58]yes25 ± 2[39,41,59]noTW b
MWC 349yes[60]yes4 ± 1[61,62]no[62]
GG Caryesno[58]yes15 ± 5[35,37,39,41,42,58]noTW b
Hen 3-298yesyes[58,63]yes20 ± 5[39,41,58,63]noTW b
CPD-52 9243yesno[58]yes[35,39,58]noyesTW b,45]
HD 327083yesno[58]yes[39,58]noyesTW b,45]
MWC 300noyesTW bno[39,64]noTW b
AS 381nono[65]abs?[39,64,65]
CPD-57 2874yesno[58]yes[35,39,58]noyesTW b,45]
Hen 3-938yesyes[54]noTW b
MWC 342noyes[60,66]
Hen 3-303nonoTW bno[63]noTW b
CD-42 11721noyes[67]no[39]noTW b
HD 87643yesno[58]yes e[39,58]noTW b
HD 62623 cyesyes[58]yes[39,58]noyesTW b,45]
Note: TW, This work; abs, in absorption; ?, uncertain detection/no value available; …, no information. a Refers to the presence of [O i] λ 5577. All sample stars show emission of [O i] λ λ 6300,6364. b Based on (unpublished) high-resolution optical spectra taken between 2005 and 2017 with FEROS at the MPG 2.2 m telescope. c A[e]SG due to early-A spectral type assignment [68,69]. d No indication of CO band features seen in a K-band spectrum (unpublished) taken on 20 October 2013 with OSIRIS at the Southern Astrophysical Research (SOAR) Telescope. e No CO emission was detected during the observations taken between 1987 and 1989 [35,36].
Table 3. IR colors of Magellanic Cloud B[e]SGs and LBVs.
Table 3. IR colors of Magellanic Cloud B[e]SGs and LBVs.
ObjectJ–HH–KW1–W2W2–W4Class
Large Magellanic Cloud
LHA 120-S 120.634 ± 0.0350.924 ± 0.0350.761 ± 0.0311.723 ± 0.051B[e]SG
LHA 120-S 220.619 ± 0.0331.289 ± 0.0331.258 ± 0.0473.328 ± 0.032B[e]SG
LHA 120-S 350.520 ± 0.0601.096 ± 0.0511.156 ± 0.0274.323 ± 0.021B[e]SG
LHA 120-S 590.661 ± 0.0370.962 ± 0.0350.988 ± 0.0313.514 ± 0.033B[e]SG
LHA 120-S 730.403 ± 0.0330.825 ± 0.0331.030 ± 0.0314.015 ± 0.027B[e]SG
LHA 120-S 890.440 ± 0.0221.030 ± 0.0361.059 ± 0.0313.289 ± 0.026B[e]SG
LHA 120-S 930.507 ± 0.0361.195 ± 0.0331.128 ± 0.0303.486 ± 0.025B[e]SG
LHA 120-S 111 a0.500 ± 0.0001.030 ± 0.000B[e]SG
LHA 120-S 1270.362 ± 0.0331.004 ± 0.0331.106 ± 0.0393.922 ± 0.028B[e]SG
LHA 120-S 1340.609 ± 0.0301.245 ± 0.0301.090 ± 0.0452.892 ± 0.035B[e]SG
LHA 120-S 1370.899 ± 0.0401.097 ± 0.0370.931 ± 0.0302.691 ± 0.045B[e]SG
LHA 120-S 96 (=S Dor)0.173 ± 0.0540.172 ± 0.0570.374 ± 0.0285.586 ± 0.022LBV
LHA 120-S 116 (=R110)0.116 ± 0.0340.161 ± 0.0360.076 ± 0.0323.391 ± 0.034LBV
LHA 120-S 128 (=R127)0.115 ± 0.0370.286 ± 0.0360.255 ± 0.0296.573 ± 0.021LBV
LHA 120-S 155 (=R71)0.027 ± 0.0350.097 ± 0.0380.069 ± 0.0337.095 ± 0.024LBV
CPD-69 463 (=R143)0.244 ± 0.0330.201 ± 0.0350.259 ± 0.0307.851 ± 0.049LBV
LHA 120-S 83 (=Sk −69 142a)0.115 ± 0.0410.287 ± 0.0410.239 ± 0.0311.609 ± 0.055LBV
Small Magellanic Cloud
LHA 115-S 60.433 ± 0.0340.709 ± 0.03190.769 ± 0.0314.037 ± 0.035B[e]SG
LHA 115-S 180.418 ± 0.0500.822 ± 0.04601.059 ± 0.0303.705 ± 0.031B[e]SG
LHA 115-S 230.221 ± 0.0380.601 ± 0.03820.946 ± 0.0312.484 ± 0.096B[e]SG
LHA 115-S 650.292 ± 0.0350.800 ± 0.03110.982 ± 0.0304.363 ± 0.027B[e]SG
LHA 115-S 52 (=R40)0.182 ± 0.0360.065 ± 0.03300.066 ± 0.0312.851 ± 0.043LBV
Note: IR photometry for all objects is taken from the 2MASS point source catalog (J, H, and K [104]), except for the stars LHA 120-S 111 [21] and LHA 120-S 89 [108], and from the WISE All-Sky Data Release (W1, W2, and W4 [105]). a Despite of the lack of WISE colors, the presence of warm dust is proven by its IR excess seen in the Spitzer data, and its IR spectrum that looks like a twin of the one of LHA 120-S 73 (see [82]).
Table 4. Confirmed and candidate B[e]SGs in the LMC. Misclassified objects are listed in the bottom part of the table.
Table 4. Confirmed and candidate B[e]SGs in the LMC. Misclassified objects are listed in the bottom part of the table.
ObjectRef.E(B–V)Ref.J–HH–KW1–W2W2–W4
Confirmed B[e]SGs
LHA 120-S 165[114]0.735 ± 0.0410.98 ± 0.0400.886 ± 0.0293.385 ± 0.037
ARDB 54[54,118]0.11[54]0.340 ± 0.0570.810 ± 0.040.402 ± 0.0232.057 ± 0.054
Uncertain or controversial classification
(VFTS 1003)[111]0.540 ± 0.0940.87 ± 0.0539
(VFTS 822)[112,113]0.56[113]0.689 ± 0.0391.261 ± 0.0350.952 ± 0.0336.09 ± 0.046
Erroneous classification
(VFTS 698)[119]0.6[119]0.436 ± 0.0300.444 ± 0.0340.585 ± 0.0309.81 ± 0.023
([L72] LH 85-10)[96]0.108 ± 0.0360.211 ± 0.048
(NOMAD1
0181-0125572)[118]aa
Note: IR photometry for all objects is taken from the 2MASS point source catalog (J, H, and K [104]) and from the WISE All-Sky Data Release (W1, W2, and W4 [105]). a The JHK magnitudes listed in SIMBAD were mistakenly taken from the paper of Levato et al. [118], but these belong to the star LHA 120-S 165.
Table 5. Confirmed and candidate B[e]SGs in the SMC. Misclassified objects are listed in the bottom part of the table.
Table 5. Confirmed and candidate B[e]SGs in the SMC. Misclassified objects are listed in the bottom part of the table.
ObjectRef.E(B–V)Ref.J–HH–KW1–W2W2–W4
Confirmed B[e]SGs
[MA93] 1116[54,125]0.42[54]0.665 ± 0.0771.084 ± 0.06891.112 ± 0.036.883 ± 0.034
Uncertain or controversial classification
(LHA 115-S 38)[124]0.13[132]0.468 ± 0.0380.879 ± 0.0381.034 ± 0.0313.978 ± 0.035
Erroneous classification
(LHA 115-N82)[122,133]0.12[133]0.488 ± 0.0401.141 ± 0.0401.133 ± 0.0312.723 ± 0.038
(LHA 115-S 29)[123]0.05[123]0.089 ± 0.0300.180 ± 0.0320.346 ± 0.0302.479 ± 0.020
(LHA 115-S 46)[123]0.05[123]0.096 ± 0.0370.204 ± 0.0400.308 ± 0.0302.108 ± 0.020
(LHA 115-S 62)[123]0.11[123]0.084 ± 0.0390.175 ± 0.0480.315 ± 0.0343.076 ± 0.024
Note: IR photometry for all objects is taken from the 2MASS point source catalog (J, H, and K [104]) and from the WISE All-Sky Data Release (W1, W2, and W4 [105]).
Table 6. Confirmed and candidate B[e]SGs in M31. Misclassified objects are listed at the bottom of the table.
Table 6. Confirmed and candidate B[e]SGs in M31. Misclassified objects are listed at the bottom of the table.
LGGSRef.J–HH–KW1–W2W2–W4
Confirmed B[e]SGs
J004320.97+414039.6[99,139]0.3581.522 ± 0.1430.983 ± 0.0515.284 ± 0.084
J004415.00+420156.2 a[99,139]0.741 ± 0.2531.510 ± 0.2100.961 ± 0.0333.645 ± 0.230
J004417.10+411928.0 b,c[99,136]0.387 ± 0.1480.853 ± 0.1490.882 ± 0.0684.455 ± 0.247
J004522.58+415034.8 c,d[136]0.684 ± 0.2230.877 ± 0.2731.091 ± 0.0394.303 ± 0.187
Uncertain or controversial classifications
(J004220.31+405123.2)[99]0.880 ± 0.0624.495 ± 0.298
(J004221.78+410013.4)[99]0.927 ± 0.0725.253 ± 0.107
(J004229.87+410551.8) e[99,139]0.870 ± 0.0454.484 ± 0.082
(J004411.36+413257.2)[139]0.187 ± 0.1230.914 ± 0.165
(J004442.28+415823.1)[99,139]0.781 ± 0.0764.994 ± 0.406
(J004444.52+412804.0) c,d[137]0.576 ± 0.1190.858 ± 0.1140.883 ± 0.0395.247 ± 0.046
(J004621.08+421308.2) d[139]0.374 ± 0.1711.283 ± 0.1281.091 ± 0.0394.303 ± 0.188
Erroneous classifications
(J004043.10+410846.0)[99,139]1.6160.523 ± 0.1620.974 ± 0.0454.030 ± 0.250
(J004057.03+405238.6)[99]
Note: IR photometry is taken from the 2MASS point source catalog (J, H, K [104]) and from the WISE All-Sky Data Release (W1, W2, W4 [105]). Colors resulting from uncertain photometric values are written in italic. a Possible contamination in the photometric bands J, W1 and W2 due to crowding. b Possible contamination in the photometric bands J and H due to crowding. c Has CO band emission [136,137]. d Has also been classified as warm hypergiant [140]. e Possible contamination in the photometric bands W1 and W2 due to crowding.
Table 7. Confirmed and candidate B[e]SGs in M33. Misclassified objects are listed at the bottom of the table.
Table 7. Confirmed and candidate B[e]SGs in M33. Misclassified objects are listed at the bottom of the table.
LGGSRef.J–HH–KW1–W2W2–W4
Confirmed B[e]SGs
J013333.22+303343.4 a[97,99,138]1.144 ± 0.2341.128 ± 0.1540.900 ± 0.0635.269 ± 0.098
J013350.12+304126.6[97,99]0.653 ± 0.0890.683 ± 0.0910.764 ± 0.0414.132 ± 0.186
Uncertain or controversial classifications
(J013324.62+302328.4)[97,99]1.050 ± 0.0474.235 ± 0.414
(J013342.78+303256.3)[99]
(J013349.28+305250.2)[99]0.746 ± 0.0545.394 ± 0.040
(J013426.11+303424.7)[97,99]1.208 ± 0.0664.845 ± 0.278
(J013459.47+303701.9)[97,99]0.898 ± 0.0534.996 ± 0.038
(J013500.30+304150.9)[97,99]0.939 ± 0.0404.142 ± 0.029
Erroneous classifications
(J013242.26+302114.1)[97,99]0.861 ± 0.0590.376 ± 0.0640.050 ± 0.0404.543 ± 0.031
(J013406.63+304147.8) b[97,138,141]0.217 ± 0.1150.249 ± 0.149
Note: IR photometry is taken from the 2MASS point source catalog (J, H, and K [104]) and from the WISE All-Sky Data Release (W1, W2, and W4 [105]). Colors resulting from uncertain photometric values are written in italic. a Has CO band absorption [138]. b Has CO band emission [138].
Table 8. Candidate B[e]SGs in M81.
Table 8. Candidate B[e]SGs in M81.
Star IDRA(J2000)Dec(J2000)VRef.
(10584-8-4)9:54:50.03+69:06:55.47[156]
(10584-4-1)9:54:54.05+69:10:23.0019.68[156]
(10584-9-1)9:55:18.97+69:08:27.5419.10[156]
Table 9. Confirmed and candidate B[e]SGs in the Milky Way.
Table 9. Confirmed and candidate B[e]SGs in the Milky Way.
ObjectRef. E ( B V ) Ref.(J–H)(H–K)(J–H) 0 (H–K) 0
Confirmed B[e]SGs
MWC 137 a[59,166]1.22[166]0.922 ± 0.0401.217 ± 0.0350.572 ± 0.0400.930 ± 0.035
MWC 349 a[62,167]∼3.2[168]1.472 ± 0.0381.603 ± 0.3690.554 ± 0.0380.851 ± 0.369
GG Car b[41,42,169]0.51[169]0.818 ± 0.0490.964 ± 0.0490.672 ± 0.0490.844 ± 0.049
Hen 3-298[41,63]1.7[63]1.009 ± 0.0651.139 ± 0.0600.522 ± 0.0650.739 ± 0.060
CPD-52 9243[50]1.7[35]0.919 ± 0.0290.948 ± 0.0260.432 ± 0.0290.548 ± 0.026
HD 327083 b[170]1.8[170]1.000 ± 0.0421.309 ± 0.1880.484 ± 0.0420.886 ± 0.188
MWC 300 a,b[171,172]1.2[172]1.150 ± 0.0561.951 ± 0.0550.806 ± 0.0561.669 ± 0.055
AS 381 b[65]2.3[65]1.285 ± 0.0291.117 ± 0.0280.625 ± 0.0290.576 ± 0.028
CPD-57 2874[47]1.75[47]0.803 ± 0.0620.678 ± 0.3040.301 ± 0.0620.267 ± 0.304
Uncertain or controversial classifications
(Hen 3-938)[54]1.64[54]1.593 ± 0.0351.487 ± 0.0341.124 ± 0.0351.101 ± 0.034
(MWC 342) a,b[173]1.5[173]1.179 ± 0.0271.121 ± 0.0250.749 ± 0.0270.768 ± 0.025
(Hen 3-303)[63]1.7[63]1.366 ± 0.0631.443 ± 0.0630.879 ± 0.0631.042 ± 0.063
(CD-42 11721) a[67]1.4–1.6[50,67]1.317 ± 0.0531.398 ± 0.0500.901 ± 0.0531.057 ± 0.050
(HD 87643) a,b[35,174]1.0[35]1.461 ± 0.2711.300 ± 0.3381.174 ± 0.2711.065 ± 0.338
(HD 62623) b[69]0.17[175]0.395 ± 0.3800.693 ± 0.3680.346 ± 0.3800.653 ± 0.368
Note: IR photometry is taken from the 2MASS point source catalog (J, H, and K [104]). a Star appears also in HAeBe catalogs (see, e.g., [160]). b Confirmed or suspected binary.

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Kraus, M. A Census of B[e] Supergiants. Galaxies 2019, 7, 83. https://0-doi-org.brum.beds.ac.uk/10.3390/galaxies7040083

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