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Sigma Orionis

Sigma Orionis (σ Ori), also known as 23 Orionis, is a young, gravitationally bound multiple star system with six components located in the constellation Orion, approximately 388 parsecs (about 1,260 light-years) from the Sun.^[1] It consists of a hierarchical triple subsystem (Aa, Ab, and B) along with three more distant companions, C, D, and the peculiar magnetic star E, all of which are early-type main-sequence stars with a combined visual magnitude of 3.81, making the system visible to the naked eye under dark skies.^[1] The system is less than 1 million years old and serves as the central ionizing source for the surrounding σ Orionis cluster, a sparse young open cluster embedded in the Orion OB1 association.^[2]^[3] The core of the system is the close spectroscopic binary Aa-Ab, where Aa is an O9V star with a mass of 17.0 M⊙ and Ab is a B0V star with a mass of 12.8 M⊙; they orbit each other in a highly eccentric (e = 0.779) period of 143.2 days at a semi-major axis of about 1.3 AU.^[1] This pair is accompanied by the B0.5V star B (11.5 M⊙), which forms a wider orbit around the Aa-Ab barycenter with a period of approximately 160 years and a separation of 42 AU (0.25 arcseconds).^[1] Components C (A2V, magnitude 9.5) and D (B2V, magnitude 6.8) are single stars at projected separations of about 4,400 AU and 5,000 AU from the triple core, respectively, while E (B2Vp, magnitude 6.7) is a helium-strong, chemically peculiar star at around 16,000 AU, notable for its strong dipolar magnetic field (7.3–7.8 kG) and rapid rotation period of 1.19 days, which causes photometric variability.^[4]^[5] As the brightest member of the σ Orionis cluster—estimated to contain over 200 confirmed members with ages of 3–5 million years and a total mass of around 225 M⊙—the system illuminates nearby nebular structures, including parts of the Horsehead Nebula, and provides a key laboratory for studying massive star formation, multiplicity, and the early evolution of high-mass stars in a relatively low-extinction environment.^[3]^[6] The cluster's proximity and youth have enabled detailed observations of its low-mass stellar and substellar population, including planetary-mass objects, revealing insights into the initial mass function and disk evolution in young stellar environments.^[3]

Nomenclature and History

Etymology and Designations

The Bayer designation σ Orionis (Sigma Orionis) was assigned by the German astronomer Johann Bayer in his 1603 star atlas Uranometria, the first comprehensive celestial atlas to systematically label stars using Greek letters followed by the Latin genitive of the constellation name, generally in order of decreasing apparent brightness within each constellation.^[7] The letter σ (sigma), the eighteenth in the Greek alphabet, reflects its relative brightness ranking among Orion's visible stars at the time.^[8] In the Flamsteed system, introduced by English astronomer John Flamsteed in his Historia Coelestis Britannica (1725), the star is designated 48 Orionis, numbering stars sequentially by increasing right ascension within each constellation.^[9] Additional modern catalog identifiers include HD 37468 from the Henry Draper Catalogue, HR 1931 from the Harvard Revised Photometry, and HIP 26549 from the Hipparcos Catalogue.^[10] Unlike brighter Orion stars such as Betelgeuse (α Orionis) or Rigel (β Orionis), which bear traditional proper names derived from Arabic or other historical origins, σ Orionis lacks any such traditional name and is known solely by its systematic designations.^[11]

Discovery and Early Observations

Sigma Orionis was omitted from Claudius Ptolemy's Almagest in the 2nd century CE, where the constellation Orion is cataloged with 66 stars but lacks any entry for this object. The star was first recorded in the 10th century by the Persian astronomer Abd al-Rahman al-Sufi in his Book of Fixed Stars, where it appears as a single bright point in Orion without formal catalog entry.^[12] In the late 16th century, Tycho Brahe measured its position during his systematic observations from Hven and included it in his posthumously published star catalog of 1597 as a solitary star of the second magnitude.^[13] Johann Bayer similarly treated it as a single star in his 1603 atlas Uranometria, assigning the Greek letter sigma and describing it as the first star in Orion's sword ("in ense, prima").^[14] The multiplicity of Sigma Orionis began to be recognized in the 18th century. In 1776, German astronomer Christian Mayer, using a refractor at the Mannheim Observatory, identified it as a double star by resolving components AB and E, and suspected an additional companion between them; this marked one of the earliest systematic efforts to catalog visual binaries.^[15] Subsequent observations refined this view: William Herschel confirmed the AB-D pair in 1779 with his reflector, while John Herschel later added further details in the early 19th century. In 1831, Wilhelm Struve discovered component C, and in 1837, Friedrich Georg Wilhelm von Struve resolved the close AB binary at 0.26 arcseconds using a Fraunhofer refractor at Pulkovo Observatory, establishing its status as a challenging visual double.^[16] By the mid-19th century, components C, D, and E were firmly distinguished, completing the recognition of the system's quadruple nature at visual scales. Modern spectroscopic investigations built on these visual discoveries. Early spectra in the 1950s, including work by G. R. Miczaika, revealed the O9.5 V classification for component A through analysis of its hydrogen and helium lines, confirming its status as a hot, massive O-type star while noting the blended contributions from nearby companions. The spectroscopic binary nature of component A was first suspected in 1904 and confirmed as double-lined in 1974 with a period of about 143 days.^[17] The complexity of the AB pair was further elucidated in 2011, when high-resolution spectroscopy from the Nordic Optical Telescope demonstrated that AB is itself a hierarchical triple, with Aa and Ab forming a double-lined spectroscopic binary with an eccentric period of 143.5 days; this inner pair orbits B with a period of approximately 160 years, as determined via radial velocity monitoring of He I lines over 2.5 years.^[18]

The Sigma Orionis Cluster

Physical Properties and Location

The Sigma Orionis cluster is a young open cluster embedded within the Orion OB1b association, where star formation commenced approximately 3 million years ago.^[19]^[20] This cluster features a core-halo structure, consisting of a dense core spanning roughly 3-5 parsecs across and hosting about 300 members, enveloped by an extended halo that reaches out to 10-20 parsecs.^[21]^[6] The overall metallicity of the cluster is comparable to that of the Sun, and its total mass is estimated at 200-300 solar masses.^[20]^[22] Positioned in the sky at right ascension 05h 38m 42s and declination -02° 36′ 00″, the cluster lies at galactic coordinates l = 206.8°, b = -17.3°.^[23] Its distance has been measured via the dynamical parallax of the central multiple star system at 387.5 ± 1.3 parsecs, while Gaia DR3 observations provide an average distance of approximately 391 parsecs for confirmed members.^[1]^[3]

Stellar and Substellar Population

The Sigma Orionis cluster hosts approximately 350 confirmed members, predominantly pre-main-sequence stars spanning a mass range from about 0.01 to 20 solar masses (M⊙). These objects are characterized by their youth, with the cluster's age estimated at around 3 million years, placing most members on Hayashi tracks in the Hertzsprung-Russell diagram. The stellar population is dominated by low- and intermediate-mass stars, with a significant fraction exhibiting signs of ongoing accretion and circumstellar activity.^[24]^[25] The initial mass function (IMF) of the cluster follows a power-law form, dN/dm ∝ m^{-α}, with α ≈ 0.6–0.8, extending consistently from the stellar regime down into the substellar domain without evidence of steepening at planetary masses. This flat or rising IMF toward lower masses indicates that brown dwarfs and planetary-mass objects form in numbers comparable to stars, challenging traditional models of isolated star formation and suggesting a continuum in the formation process across the hydrogen-burning limit. Seminal surveys have confirmed this behavior, highlighting the cluster's role in probing the low-mass end of the IMF.^[26]^[27] The substellar population includes roughly 30–50 brown dwarfs, with spectral types ranging from M6 to L5 and masses between 0.013 and 0.072 M⊙, alongside 10–20 planetary-mass objects down to approximately 3 Jupiter masses (M_J). These objects are identified through deep photometric surveys in IZJHK bands, revealing a diverse low-mass tail where isolated planetary-mass candidates, such as S Ori 70, exhibit methane absorption indicative of cool atmospheres. Membership is established via a combination of proper motions (refined by Gaia astrometry), photometric placement on cluster isochrones, and spectroscopic confirmation of youth indicators like lithium absorption and Hα emission; however, a few T-type dwarf candidates remain uncertain due to faintness and potential field contamination.^[25]^[28] The binary fraction among cluster members, particularly visual and spectroscopic pairs, is elevated compared to field populations, attributed to the system's youth where dynamical disruptions have not yet significantly altered initial multiplicities. Surveys indicate a spectroscopic binary fraction of about 10% for masses above 0.1 M⊙, rising in the low-mass regime, with wide binaries common among pre-main-sequence objects. This enhanced multiplicity underscores the cluster's value for studying binary formation mechanisms in the early stages of stellar evolution.^[29]

Protoplanetary Disks and Planet Formation

Recent high-resolution observations with the Atacama Large Millimeter/submillimeter Array (ALMA) in 2024 have revealed detailed structures in protoplanetary disks around several low-mass stars in the Sigma Orionis cluster, including prominent gaps, rings, and other substructures suggestive of ongoing planet-disk interactions. For instance, the disk surrounding the T Tauri star Haro 5-34 exhibits multiple concentric rings and gaps at scales of approximately 10-50 au, interpreted as evidence of forming protoplanets sculpting the dust distribution. These features persist despite the intense ultraviolet radiation from the nearby O9.5 V star σ Ori A, indicating that disk evolution and planet formation processes remain active in this irradiated environment.^[30]^[31] Such observations provide compelling evidence for the formation of ice and gas giant planets on solar-system-like scales within these disks, even under harsh external conditions that accelerate disk dispersal. The presence of substructures in at least seven out of eight surveyed disks implies that embedded planets with masses comparable to Jupiter could be influencing the gas and dust dynamics, countering the expectation of rapid photoevaporation truncating disk lifetimes. This resilience highlights the robustness of core accretion mechanisms in cluster settings, where massive stars dominate the radiation field.^[30]^[32] A 2025 study analyzing disk mass distributions across the cluster identified a radial gradient in disk masses, with outer regions showing depleted masses potentially linked to dynamical interactions from the runaway binary system σ Ori AB. As this high-velocity system passes through the cluster, close flybys may strip material from the outer envelopes of protoplanetary disks, contributing to mass loss beyond photoevaporative effects alone. Simulations suggest that such encounters could explain the observed truncation radii and reduced gas reservoirs in disks farther from the cluster center.^[33]^[34] Early release observations from the Euclid mission in 2025 have detected several free-floating planetary-mass objects in the Sigma Orionis field, with masses down to a few Jupiter masses, supporting an initial mass function (IMF) that extends smoothly into the planetary regime without a sharp low-mass cutoff. These isolated objects, confirmed as cluster members via proper motion and photometry, align with predictions from disk instability or ejection scenarios during the early stages of formation around low-mass stars and brown dwarfs.^[35]^[36] Protoplanetary disk frequencies in the cluster are approximately 50% for low-mass stars, consistent with the estimated age of 3-5 Myr, though this fraction decreases with proximity to the central massive star due to enhanced external photoevaporation. Infrared excess surveys indicate that disks around stars with spectral types later than M0 retain material longer, while photoevaporative winds driven by the UV flux from σ Ori A shorten lifetimes in inner regions, leading to a spatially varying dispersal rate.^[37]^[38]

The Multiple Star System

Recent Gaia DR3 astrometry (as of 2022) and kinematic analysis indicate that the σ Orionis system consists primarily of the hierarchical triple AB and likely D as bound components, while C and E are not physically associated with the core due to divergent proper motions and distances.^[3] The cluster's median distance is approximately 402 pc.^[3]

σ Orionis AB

σ Orionis AB constitutes the primary hierarchical triple system at the heart of the Sigma Orionis multiple star configuration, featuring three massive hot stars that account for the overwhelming majority of the system's luminosity and dominate the cluster's overall brightness with a combined apparent visual magnitude of 3.81. This subsystem is particularly valuable for probing the early evolutionary stages of O- and B-type stars due to its well-characterized orbits and proximity to the young stellar cluster. The structure consists of a close spectroscopic binary (Aa and Ab) orbited by a wider visual companion (B), with the entire assembly embedded in the σ Orionis cluster, whose age provides contextual constraints on the system's development. The components exhibit distinct properties reflective of their spectral classifications and youth. The primary Aa is classified as O9.5 V, with effective temperature T_eff = 35,000 ± 1,000 K, surface gravity log g = 4.20 ± 0.15, and projected rotational velocity v sin i = 135 ± 15 km s^{-1}. The companion Ab is a B0.5 V star, possessing T_eff = 31,000 ± 1,000 K, log g = 4.20 ± 0.15, and v sin i = 35 ± 5 km s^{-1}. The outer component B is a cooler B1 V star with T_eff = 29,000 ± 2,000 K, log g = 4.15 ± 0.20, and notably rapid rotation at v sin i = 250 ± 50 km s^{-1}. These parameters stem from detailed non-LTE spectroscopic modeling and atmospheric analysis using tools like FASTWIND and BONNSAI, yielding evolutionary masses of 20.0 ± 1.0 M_⊙ for Aa, 14.6 ± 0.7 M_⊙ for Ab, and 13.6 ± 0.9 M_⊙ for B.^[39] The orbital architecture underscores the hierarchical nature of the system. The inner Aa-Ab binary is a double-lined spectroscopic pair with an orbital period of 143.198 ± 0.005 days and high eccentricity e = 0.7782 ± 0.0011, resulting in a semi-major axis of 4.286 ± 0.003 mas (corresponding to roughly 1.7 AU at the system's distance of ~388 pc). The outer orbit, resolved through long-baseline interferometry with facilities like the CHARA Array, VLTI, and NPOI, features component B revolving around the Aa-Ab center of mass with a period of 159.9 years, low eccentricity e = 0.024 ± 0.005, and semi-major axis of 262.9 ± 2.2 mas (~102 AU). These measurements yield dynamical masses of 16.99 ± 0.20 M_⊙ for Aa, 12.81 ± 0.18 M_⊙ for Ab, and 11.5 ± 1.2 M_⊙ for B, providing direct constraints on the stars' gravitational interactions.^[40] A prominent discrepancy arises between these dynamical masses and evolutionary predictions: the orbital-derived values are approximately 20-30% lower than those from stellar evolution models (e.g., 20.0 ± 1.0 M_⊙ for Aa, 14.6 ± 0.7 M_⊙ for Ab, and 13.6 ± 0.8 M_⊙ for B) calibrated to the system's parameters at the cluster's nominal age. This inconsistency, observed across multiple analyses, may stem from non-coeval formation of the components, enhanced mixing or rotational effects altering evolutionary tracks, or shortcomings in models for very young massive stars with high rotation rates. Age determinations from isochrone fitting to the σ Orionis cluster yield 2-5 Myr, yet component-specific tracks imply younger ages of 0.3 ± 1.0 Myr for Aa, 0.9 ± 1.5 Myr for Ab, and 1.9 ± 1.6 Myr for B, reinforcing the potential for differential evolution within the triple.^[39]^[40]

σ Orionis C

σ Orionis C is classified as an A2 V main-sequence star. It has a visual magnitude of 8.79 and an estimated mass of 2.7 ± 0.4 M_⊙, consistent with its spectral type and the young age of the associated cluster. The effective temperature is approximately 9,100 K, placing it among cooler A-type stars. This component is separated from the brighter σ Orionis AB pair by about 11 arcseconds, corresponding to a projected physical separation of roughly 4,455 AU at a Gaia DR3 distance of approximately 405 pc. While traditionally considered a companion, recent Gaia DR3 kinematic analysis indicates it is not physically bound to the σ Orionis system due to divergent proper motions.^[3]^[41]^[16] A faint companion to σ Orionis C, designated Cb (also known as MAD-4), was detected at an angular separation of 2 arcseconds (approximately 810 AU projected), making it a wide binary system. The companion is about 5 magnitudes fainter than σ Orionis C in the K band (K ≈ 14.07), and photometry places it in the substellar regime on the cluster's color-magnitude diagram for an age of 3–5 Myr. Its estimated mass is around 0.05 M_⊙, and it has been classified as an M8 spectral type brown dwarf based on near-infrared colors and cluster isochrones. The companionship was confirmed through common proper motion with σ Orionis C and spectroscopic analysis showing lithium absorption consistent with youth and low mass. The wide separation implies an orbital period exceeding 10,000 years, with the pair likely co-formed. Recent Gaia DR3 data indicate that σ Orionis C itself has a proper motion divergent from the cluster core (μ_α* = 0.358 ± 0.028 mas yr⁻¹, μ_δ = -1.064 ± 0.027 mas yr⁻¹), confirming its non-association.^[16]^[42]^[3] σ Orionis C exhibits rapid rotation with a projected equatorial velocity of v sin i = 150 km/s, typical for young A-type stars in clusters, but shows no significant photometric variability in optical or infrared monitoring. As an intermediate-mass star, it provides a valuable anchor for calibrating stellar evolution models at the lower end of the massive star population and for studying multiplicity statistics in young environments. The C-Cb pair, in particular, contributes to understanding the formation of wide substellar companions and the initial mass function extension into the brown dwarf regime.

σ Orionis D

σ Orionis D is a B2 V star classified as a main-sequence object with a mass of 6.8 M⊙. It has a visual magnitude of 6.69, rendering it fainter than the central components of the system and thus a minor contributor to the overall brightness of σ Orionis. The star is separated from the σ Orionis AB pair by 13 arcseconds, corresponding to a projected physical separation of approximately 5,226 AU at the cluster distance of 402 pc.^[3]^[43] Spectroscopic analysis indicates a projected rotational velocity of v sin i = 180 km s⁻¹ for σ Orionis D, consistent with rapid rotation typical of early-type main-sequence stars. The effective temperature is approximately 20,600 K, yielding a luminosity of log L/L⊙ = 3.43, though cluster age effects may adjust these values slightly lower. No companions have been detected, and high-resolution spectroscopy has ruled out a single-line spectroscopic binary configuration.^[44] Astrometric measurements from Gaia DR3 place σ Orionis D at a parallax of 2.474 mas, corresponding to a distance of about 404 pc, which is consistent with the cluster's median distance of ~402 pc. Its proper motion aligns with that of the σ Orionis cluster, supporting its association with the young stellar population.^[43]

σ Orionis E

σ Orionis E is a magnetically active B-type star classified as B2 Vpe, characterized by enhanced helium lines and emission features. It has an estimated mass of approximately 8.3 M⊙ and an effective temperature of around 22,500 K. The star exhibits photometric variability between visual magnitudes 6.61 and 6.77, with an angular separation of about 41 arcseconds from the σ Orionis AB system, corresponding to a projected physical distance of roughly 17,800 AU at its Gaia DR3 distance of 433 pc. While previously considered a distant companion, recent Gaia DR3 analysis excludes it from membership in the σ Orionis cluster due to its greater distance and inconsistent kinematics.^[3]^[5]^[45] The star hosts a strong dipolar magnetic field with a surface strength of 1–2 kG, varying longitudinally between -2,300 and +3,100 G in phase with its 1.19-day rotation period. This variability is modeled using the oblique rotator framework, where the field's obliquity to the rotation axis is estimated at 47°–59°, leading to periodic changes in the observed longitudinal component. Spectroscopic monitoring since the early 2000s, including high-resolution spectropolarimetry, has refined the field geometry, revealing a predominantly dipolar structure with possible quadrupolar contributions of 3–5 kG.^[45]^[46] Photometric and spectral variations arise from magnetic spots on the surface and interactions with the stellar wind, forming a rigidly rotating magnetosphere that confines plasma and produces variable Balmer and helium emission lines, indicative of magnetically channeled accretion or wind material. Helium emission lines, particularly in He I, are prominent and phase-variable, supporting the presence of a centrifugal magnetosphere where co-rotating plasma clouds enhance line strengths at certain rotational phases.^[47]^[48] Although its age was previously aligned with the σ Orionis cluster at around 3 Myr based on earlier Gaia data, the latest Gaia DR3 measurements confirm its non-membership. The magnetic field's persistence at such a young age suggests a fossil origin, likely a remnant from the star's formation in the turbulent early stages of a nearby stellar environment, rather than ongoing dynamo activity.^[5]^[6]^[49]^[3]

Associated Features

σ Orionis IRS1

σ Orionis IRS1 is an infrared source located approximately 3″ north of the σ Orionis AB binary, at a projected separation of about 1200 AU assuming a cluster distance of 360–420 pc. It exhibits a fan-shaped morphology in mid-infrared emission, with a compact core roughly 10³ AU across and extended structure pointing away from σ Orionis AB, indicative of an ionization front shaped by the intense ultraviolet radiation from the nearby O9.5 V star in AB. High-resolution imaging has resolved IRS1 into a binary system consisting of IRS1-A and IRS1-B. IRS1-A is the brighter component, classified as an M1 spectral type T Tauri star with an estimated mass of 0.3–0.8 M⊙, while IRS1-B is a fainter M7.5 brown dwarf with a substellar mass below 0.05 M⊙. IRS1-B is embedded within a proplyd, featuring an ionized envelope undergoing photo-evaporation due to UV flux from σ Orionis AB, with a mass-loss rate on the order of 10⁻⁷ M⊙ yr⁻¹ and electron densities around 10⁶ cm⁻³. Spectroscopy reveals strong H and He I emission lines from an extended envelope around IRS1-B, providing evidence of outflows, though no shock-excited features like H₂ or [Fe II] are detected. Both components display infrared excess, with IRS1-B showing significant dust continuum veiling at approximately 50% of its flux from material at ~1000 K, likely arising from an accretion disk or heated circumstellar dust. Age estimates place IRS1-A at 0.3–1 Myr and IRS1-B at ~0.3 Myr, younger than the σ Orionis cluster median of 2–3 Myr, based on pre-main-sequence evolutionary models. The system has been monitored for variability, including X-ray fluctuations consistent with magnetic activity in young low-mass stars. Its potential origins include the photo-evaporation of a prestellar core for IRS1-B, alongside the observed multiplicity of the binary; the projected position and kinematic consistency with the cluster, as confirmed by Gaia DR3 astrometry of nearby members, support its association with σ Orionis.^[50]

Dust Wave

The infrared arc associated with the σ Orionis cluster, often referred to as the dust wave, was detected in mid-infrared images from the Spitzer Space Telescope's IRAC and MIPS instruments, as well as from the Wide-field Infrared Survey Explorer (WISE).^[51] This prominent arc-like structure is located approximately 50 arcseconds northeast of the σ Orionis AB binary system, corresponding to a projected distance of about 0.1 parsec at the cluster's distance of roughly 390 parsecs, and spans a length of around 20 arcseconds.^[51] The arc consists of dust grains at the edge of a photoevaporated molecular cloud, where ultraviolet radiation from the O9.5V primary of σ Orionis AB has ionized the surrounding interstellar medium, creating a boundary between the H II region and the denser cloud material.^[51] This structure is not a bow shock resulting from the stellar motion through the interstellar medium but rather a radiation-pressure-driven dust wave, in which dust grains are decoupled from the plasma flow and accumulated by the star's luminosity.^[51] The dust temperature in the arc is estimated at approximately 50 K for large grains, with hotter very small grains reaching up to 75 K, consistent with heating at the H II region boundary.^[51] The total dust mass of the arc is low, on the order of 2.3 × 10^{-5} solar masses, with an associated gas mass of about 7 × 10^{-5} solar masses, indicating it holds no significant reservoir of material for star formation.^[51] As a transient feature, the dust wave is expected to evolve on a timescale of roughly 0.1 million years, driven by the ongoing photoevaporation of the cloudlet.^[51] Radiative transfer and dust dynamics modeling supports this cloudlet evaporation origin, reproducing the arc's position, shape, and grain size sorting without invoking stellar wind effects.^[51] Recent analyses in the 2020s, incorporating Gaia proper motion data, further align the arc's orientation with the system's dynamical history, reinforcing the photoevaporation scenario.^[33]

References

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May 22, 2024 · A cleaned sample of sigma Orionis cluster substellar members has been produced and the initial mass function (IMF) has been estimated by ...
[35]
An ALMA Survey of Protoplanetary Disks in the σ Orionis Cluster
We use ALMA to conduct a high-sensitivity survey of dust and gas in 92 protoplanetary disks around σ Orionis members with M * ≳ 0.1 M ⊙.
[36]
Testing external photoevaporation in the σ-Orionis cluster with ...
We tested the impact of external photoevaporation on the evolution of disks in the mid-age (~3–5 Myr) σ-Orionis cluster by conducting the first combined large- ...
[37]
None
**Summary of σ Ori Aa, Ab, B from arXiv:1412.3469**
[38]
[PDF] arXiv:1610.01984v1 [astro-ph.SR] 6 Oct 2016
Oct 6, 2016 · In this paper we report spatially resolved measure- ments of the close triple system (σ Ori Aa,Ab,B) using long baseline optical/infrared ...
[39]
https://arxiv.org/pdf/1412.3469
[40]
https://arxiv.org/pdf/1610.01984
[41]
sigma orionis D
### Summary of σ Orionis D Data
[42]
table - Department of Physics and Astronomy : University of Rochester
Missing: B2 V
[43]
http://simbad.u-strasbg.fr/simbad/sim-id?Ident=sigma+orionis+D
[44]
Revisiting the rigidly rotating magnetosphere model for σ Ori E
These magnetic Ap/Bp stars exhibit periodic variability of spectral lines, photometric brightness, and longitudinal magnetic field strength that is explained in ...
[45]
The Rigidly Rotating Magnetosphere of σ Orionis E - IOPscience
We characterize the observed variability of the magnetic helium-strong star σ Ori E in terms of a recently developed rigidly rotating magnetosphere model.
[46]
Revisiting the Rigidly Rotating Magnetosphere model for σ Ori E
This model includes a substantially offset dipole magnetic field configuration, and approximately reproduces previous observational variations in longitudinal ...
[47]
Rivi: Magnetic Stars - Eso.org
As is usual with prototypes, however, they are not quite like the serial model: σ Ori E has a very high rotational velocity. Not as high as Be stars, but ...σ Ori E: The Prototype · Feros Data Of σ Ori E · Hr 7355: The New Record...
[48]
Fine structure in the Sigma Orionis cluster revealed by Gaia DR3
Apr 25, 2024 · In total, we have discovered 105 members of this complex not previously found in the literature (82 in Sigma Orionis, 19 in the Flame ...Missing: halo size
[49]
Blowing in the wind: The dust wave around σ Orionis AB
The presence of a 24 μm infrared arc-like structure near σ Ori has been noted previously by Caballero et al. (2008) (their Fig. 1, as well as Fig. 2 from ...