Alioth

Alioth, designated Epsilon Ursae Majoris (ε UMa), is the brightest star in the northern constellation Ursa Major and ranks as the 33rd brightest star in the night sky with an apparent visual magnitude of 1.77.^[1] It is a chemically peculiar A-type star of spectral class A1III-IVpkB9, characterized by strong magnetic fields and variable chemical abundances on its surface, earning it classification as an Ap (peculiar) star.^[1] Located approximately 82.6 light-years (25.3 parsecs) from Earth, Alioth lies along the curved handle of the famous Big Dipper asterism, where it marks the star closest to the bowl.^[1] The star's traditional name, Alioth, originates from the Arabic ʾalyāt al-ḥamal, meaning "the fat tail of the sheep," a reference likely tied to its position in the bear's tail within Ursa Major mythology.^[2] With a mass of about 2.91 times that of the Sun, a radius roughly 4.08 times solar, and a surface temperature around 9,200 K, Alioth shines with a luminosity approximately 107 times greater than the Sun's, appearing as a brilliant white point of light to the naked eye. It has an estimated age of around 300 million years.^[3] Its equatorial coordinates are right ascension 12h 54m 01.7s and declination +55° 57' 35", with a proper motion of +111.91 mas/year in right ascension and -8.24 mas/year in declination.^[1] Alioth exhibits subtle photometric variability due to its rotation and magnetic activity, with a projected rotational velocity of 33 km/s and a weak but detectable dipolar magnetic field estimated at up to +128 G and -64 G at its poles.^[4] As a rapidly rotating Ap star, it displays surface abundance patches of elements like calcium, chromium, iron, magnesium, and silicon, which have been mapped through Doppler imaging techniques. No known exoplanets orbit Alioth, and it remains a single star system, though its peculiar chemistry continues to make it a subject of study in stellar astrophysics.^[1]

Stellar characteristics

Physical properties

Alioth is a massive A-type star with a mass of 2.91 M⊙, significantly greater than the Sun's, which places it among the more evolved members of its spectral class.^[3] Its radius measures 4.29 R⊙, making it substantially larger than the Sun and contributing to its high luminosity of 104.4 ± 9.3 L⊙.^[5] The effective temperature of the star's photosphere is 9,200 ± 200 K, indicative of its hot, white appearance, while the surface gravity is log g = 3.6 (cgs), reflecting its expanded envelope consistent with post-main-sequence evolution.^[3]

Property	Value	Unit
Mass	2.91	M⊙
Radius	4.29	R⊙
Luminosity	104.4 ± 9.3	L⊙
Effective temperature	9,200 ± 200	K
Surface gravity	log g = 3.6	(cgs)

These parameters position Alioth on the Hertzsprung-Russell diagram near the transition from the main sequence to the subgiant branch, where stars of its mass begin to exhaust core hydrogen and expand.^[3] With an estimated age of approximately 300 million years, derived from its membership in the Ursa Major moving group, Alioth represents a relatively young but evolving stellar system, having spent much of its life fusing hydrogen in its core before entering this transitional phase.^[6]

Spectral classification and variability

Alioth is classified as an A0p Cr star, a chemically peculiar A-type star of luminosity class III-IV exhibiting spectral features indicative of an α² Canum Venaticorum (α² CVn) variable.^[7] This classification reflects its evolved luminosity class (III-IV) and peculiarities in line strengths, including enhanced chromium and europium lines, with the "p" denoting chemical anomalies driven by atomic diffusion in its stably stratified atmosphere. The star's spectrum shows a white-blue hue, consistent with its B-V color index of -0.02. As the brightest member of Ursa Major, Alioth has an apparent visual magnitude of 1.77, making it a prominent naked-eye object, while its absolute magnitude is approximately -0.2.^[8] It displays photometric variability typical of α² CVn stars, with small-amplitude brightness changes of about 0.02 magnitudes in the V band, resulting in a double-wave light curve modulated by rotation.^[9] These variations arise from surface abundance inhomogeneities that alter opacity across different wavelengths, with larger amplitudes in the ultraviolet (up to 0.12 mag) decreasing toward the infrared.^[9] The star's chemical peculiarities include overabundances of elements such as chromium (mean log ε(Cr) ≈ -5.7), iron (log ε(Fe) ≈ -4.65), strontium, manganese (log ε(Mn) ≈ -5.6), and europium, contrasted by depletions in titanium (log ε(Ti) ≈ -7.6).^[7] Silicon abundances also vary across the surface, contributing to the peculiar spectral profile. These anomalies stem from radiative diffusion processes, which segregate elements based on their ionization and migration velocities in the absence of significant convection. Observations reveal periodic variations in spectral lines of these elements, tied to the star's rotation, with enhancements concentrated at magnetic poles and depletions at the equator for heavy metals like Cr, Fe, and Sr.

Magnetic field and rotation

Alioth exhibits a relatively weak magnetic field compared to other chemically peculiar Ap stars, with a polar field strength of approximately 400 G. This is roughly 600–1600 times the average surface magnetic field of Earth (0.25–0.65 G) but about 10 times weaker than the field in prototypical Ap stars such as α Canum Venaticorum, which has longitudinal field extrema exceeding 4000 G.^[10]^[11] The field is predominantly dipolar in geometry, as inferred from its sinusoidal variation over the rotation cycle.^[10] The longitudinal component of the magnetic field, measured via the Zeeman effect in circularly polarized spectra, varies smoothly from +128 G to -64 G across the 5.0887-day rotation period.^[10] Earlier measurements suggested larger variations up to +1100 G and -300 G, but high-precision observations confirm the weaker values, resolving prior discrepancies.^[12] The obliquity of the magnetic axis relative to the rotation axis is estimated at 46°–90°, with detailed modeling of surface distributions favoring values around 62°–64°.^[10]^[12] This rapid rotation, with an equatorial velocity of v sin i ≈ 25 km s⁻¹, induces stellar oblateness and Doppler shifts in spectral lines, broadening them and contributing to the observed line profile variations.^[12] The misaligned magnetic and rotation axes cause the field to modulate the distribution of chemical elements on the surface, forming spots enriched in metals like Cr, Fe, and Mn at the magnetic poles.^[12] As these spots rotate into and out of view, they produce periodic changes in brightness (up to 0.02 mag) and spectral features, consistent with the oblique rotator model. No stellar companions have been confirmed to influence the rotation or variability, with radial velocity changes attributed solely to the rotational modulation of surface inhomogeneities.

Kinematics and group membership

Distance and proper motion

Alioth occupies the position in the sky at equatorial coordinates RA 12h 54m 01.8s, Dec +55° 57′ 35″ (J2000.0).^[13] The most precise measurement of its distance comes from the Gaia DR3 parallax of 39.51 ± 0.16 mas, yielding a distance of 82.6 ± 0.3 light-years (25.3 ± 0.1 pc).^[13] This places Alioth within the local volume of the galaxy, allowing for detailed kinematic analysis. Alioth exhibits proper motion components of +111.91 ± 0.16 mas/yr in right ascension and -8.24 ± 0.14 mas/yr in declination, as measured by Gaia DR3.^[13] These values indicate the star's transverse motion across the celestial sphere relative to the solar system. The corresponding tangential velocity is 14.3 km/s.^[13] Combined with its radial velocity of -12.3 km/s, the full three-dimensional space motion of Alioth is characterized by velocity components U = 14 km/s (toward the galactic center), V = 2 km/s (in the direction of galactic rotation), and W = -9 km/s (toward the north galactic pole).

Velocity Component	Value (km/s)
Radial velocity	-12.3
Tangential velocity	14.3
U (galactocentric)	14
V (galactic rotation)	2
W (north galactic pole)	-9

These kinematic parameters confirm Alioth's membership in the Ursa Major moving group, where it shares similar space velocities with other members.

Ursa Major moving group

The Ursa Major moving group is a nearby stellar association consisting of approximately 60 stars that share similar space velocities and ages of 300–500 million years, making it the closest such group to the Solar System.^[14] This association is characterized by a mean space velocity of (U, V, W) ≈ (14, 2, -9) km/s relative to the Sun and a low velocity dispersion of about 3 km/s in the core members, indicating a coherent kinematic structure.^[15] The group's formation is thought to represent the remnants of one or more dissolved open clusters, with the stars now dispersed but retaining their common origin through shared motion and evolutionary history.^[14] Alioth (ε UMa, HD 112185) is a confirmed nucleus member of the Ursa Major moving group, based on its convergent proper motion and radial velocity aligning closely with the group's mean kinematics.^[14] Membership was initially established through Hipparcos astrometric data, which provided precise parallaxes and proper motions to identify the coherent velocity pattern among candidate stars.^[14] Subsequent analysis using Gaia data has refined and confirmed this association, incorporating higher-precision measurements to validate Alioth's position within the group's spatial and velocity distribution. The group's age of 300–500 million years is consistent with Alioth's estimated evolutionary stage, placing it among intermediate-mass A-type stars on the main sequence. Members of the Ursa Major moving group, including Alioth, exhibit shared chemical compositions with roughly solar metallicity ([Fe/H] ≈ 0.03 ± 0.07 dex) and homogeneous abundances in elements like carbon, oxygen, and barium, supporting a common birthplace in a now-dissolved cluster environment.^[16] This kinematic and chemical coherence provides key insights into the dynamical evolution of nearby stellar populations.

Nomenclature and etymology

Traditional names

The primary traditional name for ε Ursae Majoris is Alioth, derived from the Arabic phrase ʿalyat al-ḥamal, meaning "fat tail of the sheep," a reference to the star's position at the base of the tail in the Ursa Major constellation.^[17] This etymology traces back to medieval Arabic astronomical texts and was documented in classical references such as those compiled by Richard Hinckley Allen.^[2] In Hindu astronomical tradition, the star is known as Añgiras, named after a Vedic sage who was one of the Saptarishi (seven great sages) associated with the stars of the Big Dipper asterism. This identification appears in historical accounts by the Persian scholar Al-Biruni, linking the star to figures in ancient Indian cosmology.^[2] The Chinese name for Alioth is Yù Héng (玉衡), meaning "jade sighting tube" or "jade balance," denoting its role as the fifth star in the Běi Dǒu (Northern Dipper) asterism, a key element in traditional Chinese celestial navigation and cosmology.^[18] Historically, it was also referred to as Běi Dǒu wǔ (北斗五), the "Fifth Star of the Northern Dipper," and designated as Mu 5 within Chinese stellar catalogs.^[19] The name Alioth was officially approved by the International Astronomical Union (IAU) Working Group on Star Names on June 30, 2016, as part of efforts to standardize proper names reflecting diverse cultural heritages.^[17]

Astronomical designations

Alioth holds the Bayer designation ε Ursae Majoris (Epsilon Ursae Majoris), assigned by Johann Bayer in his 1603 Uranometria atlas based on the star's position in the constellation rather than its brightness; despite being the brightest star in Ursa Major, it received the fifth Greek letter because Bayer cataloged the stars from west to east across the figure.^[20]^[18] The Flamsteed designation for Alioth is 77 Ursae Majoris, as numbered by John Flamsteed in his 1725 Historia Coelestis Britannica, where stars in each constellation are ordered by increasing right ascension.^[21] In modern catalogs, Alioth is listed as HD 112185 in the Henry Draper Catalogue, which classifies stars by spectral type.^[21] It appears as HIP 62956 in the Hipparcos Catalogue, providing precise astrometric data from the 1990s satellite mission.^[21] The Gaia mission's Data Release 3 assigns it the identifier Gaia DR3 1576683529448755328, offering high-precision parallax and proper motion measurements.^[21] Alioth lacks an official variable star designation from the International Variable Star Index (VSX), but it is classified as an α² Canum Venaticorum (α² CVn) variable due to its periodic photometric and spectroscopic variations driven by rotation and magnetic activity, with a small photometric amplitude of about 0.02 magnitudes over its 5.1-day rotation period.^[21]^[22] Within the constellation Ursa Major, Alioth occupies a prominent position as the brightest member and forms the first star in the handle of the Big Dipper asterism, following Megrez and preceding Mizar and Alkaid.^[23]^[20]

Observational history

Early records

Alioth, the brightest star in the constellation Ursa Major, is a prominent circumpolar object visible year-round from latitudes in the northern hemisphere above approximately 40°N, where it can reach altitudes of up to about 70° depending on the observer's location.^[18] In ancient Greek astronomy, Alioth was catalogued as part of Ursa Major in Ptolemy's Almagest during the 2nd century CE, where it was classified as a third-magnitude star within the bear's hindquarters. Chinese astronomers documented Alioth around the 4th century BCE in Shi Shen's star catalogue, identifying it as the fifth star (Yùhéng, or "Jade Transverse") in the asterism Běi Dǒu (Northern Dipper), a key component of the larger constellation.^[24] In Islamic astronomy, Abd al-Rahman al-Sufi described Alioth in his Book of Fixed Stars (completed around 964 CE) as a second-magnitude star in Ursa Major, noting its position near the tail and its brightness relative to neighboring stars like Mizar.^[25] During the medieval period in Europe, Alioth featured in navigational asterisms derived from Ptolemaic traditions, as outlined in Johannes de Sacrobosco's De Sphaera Mundi (c. 1230), which emphasized the utility of Ursa Major's stars for determining direction and latitude at sea.^[26] Early observers across these traditions did not note any variability in Alioth's brightness, consistent with its small amplitude of less than 0.1 magnitude, which remained undetected until modern instrumental analysis.^[27]

Modern studies

The variability of Alioth (ε UMa) was first recognized in the early 20th century through observations of its peculiar spectral lines, which showed periodic changes attributed to surface chemical inhomogeneities. Photometric variations were subsequently confirmed, leading to its classification as an α² CVn variable in the 1950s, a category for chemically peculiar A stars exhibiting rotational modulation due to strong magnetic fields and uneven element distributions.^[4] The magnetic field of Alioth was first definitively measured in the late 20th century using Zeeman splitting in high-resolution spectra, revealing a relatively weak but oblique dipolar configuration with extrema of approximately +128 G and -64 G. Earlier attempts in the 1950s by Babcock failed to detect the field due to its low strength, but subsequent studies in the 1980s and 1990s confirmed its presence through circular polarization observations. In the 2000s, observations with the Navy Precision Optical Interferometer (NPOI) helped confirm the absence of close companions. More recent high-resolution spectropolarimetry has refined the topology, showing a predominantly poloidal field with local surface strengths of several hundred Gauss.^[4]^[28] Gaia Data Release 2 (2018) delivered precise astrometry for Alioth, yielding a parallax of 39.94 ± 0.27 mas (corresponding to a distance of about 25 parsecs) and proper motions of μ_α cos δ = 110.3 ± 0.3 mas/yr and μ_δ = -9.5 ± 0.3 mas/yr, significantly improving prior Hipparcos measurements. Gaia DR3 (2022) further enhanced these values to a parallax of 39.51 ± 0.20 mas, proper motions of μ_α cos δ = 111.91 ± 0.23 mas/yr and μ_δ = -8.24 ± 0.19 mas/yr, and confirmed the absence of close stellar or substellar companions through non-detection of astrometric perturbations or orbital signatures, dispelling earlier suspicions of a spectroscopic binary based on radial velocity wobbles; wide common proper motion companions are cataloged but likely unbound.^[29]^[1] High-resolution spectroscopy in the 2010s, including least-squares deconvolution techniques, confirmed Alioth's rotational period of 5.095 days and revealed an obliquity of about 70° between the magnetic and rotational axes, driving the observed spectral and photometric variations. These studies highlighted enhancements of elements like chromium and manganese at magnetic poles, with Doppler imaging maps showing ring-like distributions around the equator.^[30] Despite historical suggestions of companions from apparent radial velocity variations and a 2008 model proposing a 14.7 Jupiter-mass substellar object in an eccentric orbit, Gaia data indicate no such close bodies exist, attributing variations to rotational effects and surface spots. Unresolved questions persist regarding long-term magnetic field evolution and potential distant companions. Future observations with TESS for refined variability monitoring and JWST for infrared spectroscopy could probe these, but as of November 2025, no major updates beyond Gaia DR3 have emerged, with ongoing ground-based campaigns tracking cycle modulations.^[29]

Cultural significance

In Greek mythology, Alioth forms part of the constellation Ursa Major, which depicts the nymph Callisto, a follower of Artemis who was seduced by Zeus and subsequently transformed into a bear by the jealous Hera; to prevent her from descending into the underworld, Zeus placed her among the stars as the Great Bear, with Alioth positioned in the tail closest to the body.^[31]^[23] This tale underscores themes of divine intervention and eternal vigilance, as Hera further influenced the ocean deities Oceanus and Tethys to keep the bear circling the northern sky without setting.^[31] In Hindu mythology, Alioth is identified as Añgiras, one of the revered Saptarishi—the seven great sages—who are personified by the prominent stars of the Ursa Major asterism, symbolizing wisdom, cosmic order, and the transmission of Vedic knowledge across generations.^[23] These sages, including Añgiras as a mediator between humans and gods, are said to have composed sacred hymns and guided spiritual enlightenment, with the asterism serving as a celestial reminder of their enduring legacy in the night sky.^[23] Within Chinese mythology and imperial astronomy, Alioth is known as Yù Héng, the fifth star in the Běi Dǒu (Northern Dipper) asterism, representing the "jade sighting tube"—an instrument symbolizing imperial measurement and cosmic harmony—and was integral to determining seasonal calendars, solstices, and auspicious timings for rituals.^[18]^[32] The Northern Dipper's rotation around the pole was observed to track time and predict events, with its stars embodying deities that governed fate, lifespan, and destiny in Daoist cosmology, reflecting a belief in celestial influence over human affairs.^[33]^[34] Alioth's position as the first star in the Big Dipper's handle makes it a key identifier for the asterism, facilitating circumpolar orientation and serving as a navigational aid to locate Polaris by extending a line from the bowl's outer stars, Dubhe and Merak.^[35] Historically, this configuration supported Viking navigators in charting northern routes at night by aligning with Polaris for true north, while Polynesian voyagers incorporated the Big Dipper into their star path knowledge for wayfinding across the Pacific, particularly in northern latitudes where the asterism's reliability aided long-distance voyages.^[36]^[37]^[38] Across these traditions, Alioth carries symbolic associations with direction and guidance through its navigational utility, balance via its role in Chinese imperial measurements and fate determination, and seasonal cycles as part of the ever-visible circumpolar bear in myths that align with annual hunts or cosmic rhythms.^[31]^[33]

Namesakes and modern references

The USS Alioth (AK-109) was a Crater-class cargo ship commissioned by the United States Navy on November 19, 1943, during World War II, explicitly named after the star Alioth in the constellation Ursa Major to honor its prominence as one of the brightest stars visible in the northern sky.^[39] The vessel served primarily in supply operations across the Pacific Theater until its decommissioning in 1946, exemplifying the Navy's tradition of naming ships after notable celestial bodies to evoke navigational reliability.^[40] In scientific contexts, the name Alioth has been retained and formally approved by the International Astronomical Union in 2016 as the proper name for ε Ursae Majoris, facilitating its use in catalogs and observations without additional designations.^[41] While the IAU's NameExoWorlds contests have assigned names to numerous exoplanets and host stars since 2015, no exoplanetary systems have yet been named after Alioth, though the process allows for such thematic namings based on prominent stars.^[42] Modern references to Alioth often highlight its role as a key navigational aid in the Big Dipper asterism, emphasizing its brightness (magnitude 1.77) and position for stargazing simulations. In video games, the Alioth star system features prominently in Star Trek: Bridge Commander (2002), where players engage in missions involving the destruction of a star in the system, drawing on the real star's coordinates for authenticity.^[43] Similarly, the Alioth system appears in the Elite series, including Frontier: Elite II (1993), as a habitable planetary system modeled after the star's location in Ursa Major.^[44] In popular media, Alioth serves as the name of a trans-temporal entity in the Marvel Cinematic Universe, first appearing as a void guardian in the series Loki (2021) and returning in Deadpool & Wolverine (2024), where its cloud-like form consumes multiversal variants, though this usage diverges from astronomical lore to focus on cosmic peril.^[45] Astronomy software and planetariums frequently feature Alioth as a highlighted object for demonstrating Ursa Major's rotation and pointer function toward Polaris, as seen in tools like Stellarium, which renders its real-time position for educational simulations.^[46] No major new namings or entities after Alioth have emerged since 2023, with modern invocations continuing to underscore its utility in orientation rather than symbolic mythology.^[41]