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Vega

October 20, 2023

"Star Vega" redirects here. For the psychologist, see Star Vega (psychologist). For other uses, see Vega (disambiguation).

Vega is the brightest star in the northern constellation of Lyra. It has the Bayer designation α Lyrae, which is Latinised to Alpha Lyrae and abbreviated Alpha Lyr or α Lyr. This star is relatively close at only 25 light-years (7.7 parsecs) from the Sun, and one of the most luminous stars in the Sun's neighborhood. It is the fifth-brightest star in the night sky, and the second-brightest star in the northern celestial hemisphere, after Arcturus.

Vega
Location of Vega (circled)
Observation data
Epoch J2000.0      Equinox J2000.0
Constellation Lyra
Pronunciation /ˈvɡə/[1][2][3] or /ˈvɡə/[2]
Right ascension 18h 36m 56.33635s[4]
Declination +38° 47′ 01.2802″[4]
Apparent magnitude (V) +0.026[5] (−0.02 – +0.07)[6]
Characteristics
Evolutionary stage Main sequence
Spectral type A0Va[7]
U−B color index 0.00[8]
B−V color index 0.00[8]
Variable type Delta Scuti[6]
Astrometry
Radial velocity (Rv)−13.9±0.9[9] km/s
Proper motion (μ) RA: 200.94[4] mas/yr
Dec.: 286.23[4] mas/yr
Parallax (π)130.23 ± 0.36 mas[4]
Distance25.04 ± 0.07 ly
(7.68 ± 0.02 pc)
Absolute magnitude (MV)+0.582[10]
Details
Mass2.135±0.074[11] M
Radius2.362–2.818[11] R
Luminosity40.12±0.45[11] L
Surface gravity (log g)4.1±0.1[12] cgs
Temperature9,602±180[13] (8,152–10,060 K)[11][note 1] K
Metallicity [Fe/H]−0.5[13] dex
Rotation16.5 h[14]
Rotational velocity (v sin i)20.48±0.11[11] km/s
Age455±13[11] Myr
Other designations
Wega[15], Lucida Lyrae[16], Alpha Lyrae, α Lyrae, 3 Lyrae, BD+38°3238, GJ 721, HD 172167, HIP 91262, HR 7001, SAO 67174, LTT 15486[17]
Database references
SIMBADdata

Vega has been extensively studied by astronomers, leading it to be termed "arguably the next most important star in the sky after the Sun".[18] Vega was the northern pole star around 12,000 BCE and will be so again around the year 13,727, when its declination will be +86° 14′.[19] Vega was the first star other than the Sun to have its image and spectrum photographed.[20][21] It was one of the first stars whose distance was estimated through parallax measurements. Vega has functioned as the baseline for calibrating the photometric brightness scale and was one of the stars used to define the zero point for the UBV photometric system.

Vega is only about a tenth of the age of the Sun, but since it is 2.1 times as massive, its expected lifetime is also one tenth of that of the Sun; both stars are at present approaching the midpoint of their main sequence lifetimes. Compared with the Sun, Vega has a lower abundance of elements heavier than helium.[13] Vega is also a variable star that varies slightly in brightness. It is rotating rapidly with a velocity of 236 km/s at the equator. This causes the equator to bulge outward due to centrifugal effects, and, as a result, there is a variation of temperature across the star's photosphere that reaches a maximum at the poles. From Earth, Vega is observed from the direction of one of these poles.[22]

Based on observations of more infrared radiation than expected, Vega appears to have a circumstellar disk of dust. This dust is likely to be the result of collisions between objects in an orbiting debris disk, which is analogous to the Kuiper belt in the Solar System.[23] Stars that display an infrared excess due to dust emission are termed Vega-like stars.[24] In 2021, a candidate ultra-hot Neptune on a 2.43-day orbit around Vega was discovered with the radial velocity method, additionally, another possible Saturn-mass signal with a period of about 200 days.[25]

Nomenclature Edit

 
Vega is the brightest star in the constellation of Lyra.

α Lyrae (Latinised to Alpha Lyrae) is the star's Bayer designation. The traditional name Vega (earlier Wega[15]) comes from a loose transliteration of the Arabic word wāqi' (Arabic: واقع) meaning "falling" or "landing", via the phrase an-nasr al-wāqi' (Arabic: النّسر الْواقع), "the falling eagle".[26] In 2016, the International Astronomical Union (IAU) organized a Working Group on Star Names (WGSN)[27] to catalog and standardize proper names for stars. The WGSN's first bulletin of July 2016[28] included a table of the first two batches of names approved by the WGSN; which included Vega for this star. It is now so entered in the IAU Catalog of Star Names.[29]

Observation Edit

 
The Summer Triangle

Vega can often be seen near the zenith in the mid-northern latitudes during the evening in the Northern Hemisphere summer.[30] From mid-southern latitudes, it can be seen low above the northern horizon during the Southern Hemisphere winter. With a declination of +38.78°, Vega can only be viewed at latitudes north of 51° S. Therefore, it does not rise at all anywhere in Antarctica or in the southernmost part of South America, including Punta Arenas, Chile (53° S). At latitudes to the north of 51° N, Vega remains continuously above the horizon as a circumpolar star. Around July 1, Vega reaches midnight culmination when it crosses the meridian at that time.[31]

 
The path of the north celestial pole among the stars due to the precession. Vega is the bright star near the bottom

Each night the positions of the stars appear to change as the Earth rotates. However, when a star is located along the Earth's axis of rotation, it will remain in the same position and thus is called a pole star. The direction of the Earth's axis of rotation gradually changes over time in a process known as the precession of the equinoxes. A complete precession cycle requires 25,770 years,[32] during which time the pole of the Earth's rotation follows a circular path across the celestial sphere that passes near several prominent stars. At present the pole star is Polaris, but around 12,000 BCE the pole was pointed only five degrees away from Vega. Through precession, the pole will again pass near Vega around 14,000 CE.[33] Vega is the brightest of the successive northern pole stars.[15] In 210,000 years, Vega will become the brightest star in the night sky,[34] and will peak in brightness in 290,000 years with an apparent magnitude of –0.81.[34]

This star lies at a vertex of a widely spaced asterism called the Summer Triangle, which consists of Vega plus the two first-magnitude stars Altair, in Aquila, and Deneb in Cygnus.[30] This formation is the approximate shape of a right triangle, with Vega located at its right angle. The Summer Triangle is recognizable in the northern skies for there are few other bright stars in its vicinity.[35]

Observational history Edit

 
Astrophoto of Vega
 
"On the night of July 16–17, 1850, Whipple and Bond made the first daguerreotype of a star (Vega)"

Astrophotography, the photography of celestial objects, began in 1840 when John William Draper took an image of the Moon using the daguerreotype process. On 17 July 1850, Vega became the first star (other than the Sun) to be photographed, when it was imaged by William Bond and John Adams Whipple at the Harvard College Observatory, also with a daguerreotype.[15][20][36] In August 1872, Henry Draper took a photograph of Vega's spectrum, the first photograph of a star's spectrum showing absorption lines.[21] Similar lines had already been identified in the spectrum of the Sun.[37] In 1879, William Huggins used photographs of the spectra of Vega and similar stars to identify a set of twelve "very strong lines" that were common to this stellar category. These were later identified as lines from the Hydrogen Balmer series.[38] Since 1943, the spectrum of this star has served as one of the stable anchor points by which other stars are classified.[39]

The distance to Vega can be determined by measuring its parallax shift against the background stars as the Earth orbits the Sun. The first person to publish a star's parallax was Friedrich G. W. von Struve, when he announced a value of 0.125 arcsecond (0.125″) for Vega.[40] Friedrich Bessel was skeptical about Struve's data, and, when Bessel published a parallax of 0.314″ for the star system 61 Cygni, Struve revised his value for Vega's parallax to nearly double the original estimate. This change cast further doubt on Struve's data. Thus most astronomers at the time, including Struve, credited Bessel with the first published parallax result. However, Struve's initial result was actually close to the currently accepted value of 0.129″,[41][42] as determined by the Hipparcos astrometry satellite.[4][43][44]

The brightness of a star, as seen from Earth, is measured with a standardized, logarithmic scale. This apparent magnitude is a numerical value that decreases in value with increasing brightness of the star. The faintest stars visible to the unaided eye are sixth magnitude, while the brightest in the night sky, Sirius, is of magnitude −1.46. To standardize the magnitude scale, astronomers chose Vega and several similar stars and averaged their brightness to represent magnitude zero at all wavelengths. Thus, for many years, Vega was used as a baseline for the calibration of absolute photometric brightness scales.[45] However, this is no longer the case, as the apparent magnitude zero point is now commonly defined in terms of a particular numerically specified flux. This approach is more convenient for astronomers, since Vega is not always available for calibration and varies in brightness.[46]

The UBV photometric system measures the magnitude of stars through ultraviolet, blue and yellow filters, producing U, B and V values, respectively. Vega is one of six A0V stars that were used to set the initial mean values for this photometric system when it was introduced in the 1950s. The mean magnitudes for these six stars were defined as: UB = BV = 0. In effect, the magnitude scale has been calibrated so that the magnitude of these stars is the same in the yellow, blue and ultraviolet parts of the electromagnetic spectrum.[47] Thus, Vega has a relatively flat electromagnetic spectrum in the visual region—wavelength range 350–850 nanometers, most of which can be seen with the human eye—so the flux densities are roughly equal; 2,000–4,000 Jy.[48] However, the flux density of Vega drops rapidly in the infrared, and is near 100 Jy at micrometers.[49]

Photometric measurements of Vega during the 1930s appeared to show that the star had a low-magnitude variability on the order of ±0.03 magnitude (around ±2.8%[note 2] luminosity). This range of variability was near the limits of observational capability for that time, and so the subject of Vega's variability has been controversial. The magnitude of Vega was measured again in 1981 at the David Dunlap Observatory and showed some slight variability. Thus it was suggested that Vega showed occasional low-amplitude pulsations associated with a Delta Scuti variable.[50] This is a category of stars that oscillate in a coherent manner, resulting in periodic pulsations in the star's luminosity.[51] Although Vega fits the physical profile for this type of variable, other observers have found no such variation. Thus the variability was thought to possibly be the result of systematic errors in measurement.[52][53] However, a 2007 article surveyed these and other results, and concluded that "A conservative analysis of the foregoing results suggests that Vega is quite likely variable in the 1–2% range, with possible occasional excursions to as much as 4% from the mean".[54] Also, a 2011 article affirms that "The long-term (year-to-year) variability of Vega was confirmed".[55]

Vega became the first solitary main-sequence star beyond the Sun known to be an X-ray emitter when in 1979 it was observed from an imaging X-ray telescope launched on an Aerobee 350 from the White Sands Missile Range.[56] In 1983, Vega became the first star found to have a disk of dust. The Infrared Astronomical Satellite (IRAS) discovered an excess of infrared radiation coming from the star, and this was attributed to energy emitted by the orbiting dust as it was heated by the star.[57]

Physical characteristics Edit

Vega's spectral class is A0V, making it a blue-tinged white main-sequence star that is fusing hydrogen to helium in its core. Since more massive stars use their fusion fuel more quickly than smaller ones, Vega's main-sequence lifetime is roughly one billion years, a tenth of the Sun's.[58] The current age of this star is about 455 million years,[11] or up to about half its expected total main-sequence lifespan. After leaving the main sequence, Vega will become a class-M red giant and shed much of its mass, finally becoming a white dwarf. At present, Vega has more than twice the mass[22] of the Sun and its bolometric luminosity is about 40 times the Sun's. Because it is rotating rapidly, approximately once every 16.5 hours,[14] and seen nearly pole-on, its apparent luminosity, calculated assuming it was the same brightness all over, is about 57 times the Sun's.[12] If Vega is variable, then it may be a Delta Scuti type with a period of about 0.107 day.[50]

Most of the energy produced at Vega's core is generated by the carbon–nitrogen–oxygen cycle (CNO cycle), a nuclear fusion process that combines protons to form helium nuclei through intermediary nuclei of carbon, nitrogen and oxygen. This process becomes dominant at a temperature of about 17 million K,[59] which is slightly higher than the core temperature of the Sun, but is less efficient than the Sun's proton–proton chain fusion reaction. The CNO cycle is highly temperature sensitive, which results in a convection zone about the core[60] that evenly distributes the 'ash' from the fusion reaction within the core region. The overlying atmosphere is in radiative equilibrium. This is in contrast to the Sun, which has a radiation zone centered on the core with an overlying convection zone.[61]

The energy flux from Vega has been precisely measured against standard light sources. At 5,480 Å, the flux density is 3,650 Jy with an error margin of 2%.[62] The visual spectrum of Vega is dominated by absorption lines of hydrogen; specifically by the hydrogen Balmer series with the electron at the n=2 principal quantum number.[63][64] The lines of other elements are relatively weak, with the strongest being ionized magnesium, iron and chromium.[65] The X-ray emission from Vega is very low, demonstrating that the corona for this star must be very weak or non-existent.[66] However, as the pole of Vega is facing Earth and a polar coronal hole may be present,[56][67] confirmation of a corona as the likely source of the X-rays detected from Vega (or the region very close to Vega) may be difficult as most of any coronal X-rays would not be emitted along the line of sight.[67][68]

Using spectropolarimetry, a magnetic field has been detected on the surface of Vega by a team of astronomers at the Observatoire du Pic du Midi. This is the first such detection of a magnetic field on a spectral class A star that is not an Ap chemically peculiar star. The average line of sight component of this field has a strength of −0.6±0.3 gauss (G).[69] This is comparable to the mean magnetic field on the Sun.[70] Magnetic fields of roughly 30 G have been reported for Vega, compared to about 1 G for the Sun.[56] In 2015, bright starspots were detected on the star's surface—the first such detection for a normal A-type star, and these features show evidence of rotational modulation with a period of 0.68 day.[71]

Rotation Edit

Vega has a rotation period of 12.5 hours,[14] much faster than the Sun's rotational period but similar to, and slightly slower than, those of Jupiter and Saturn. Because of that, Vega is significantly oblate like those two planets.

When the radius of Vega was measured to high accuracy with an interferometer, it resulted in an unexpectedly large estimated value of 2.73±0.01 times the radius of the Sun. This is 60% larger than the radius of the star Sirius, while stellar models indicated it should only be about 12% larger. However, this discrepancy can be explained if Vega is a rapidly rotating star that is being viewed from the direction of its pole of rotation. Observations by the CHARA array in 2005–06 confirmed this deduction.[12]

 
Size comparison of Vega (left) to the Sun (right)

The pole of Vega—its axis of rotation—is inclined no more than five degrees from the line-of-sight to the Earth. At the high end of estimates for the rotation velocity for Vega is 236.2±3.7 km/s[11] along the equator, much higher than the observed (i.e. projected) rotational velocity because Vega is seen almost pole-on. This is 88% of the speed that would cause the star to start breaking up from centrifugal effects.[11] This rapid rotation of Vega produces a pronounced equatorial bulge, so the radius of the equator is 19% larger than the polar radius. (The estimated polar radius of this star is 2.362±0.012 solar radii, while the equatorial radius is 2.818±0.013 solar radii.[11]) From the Earth, this bulge is being viewed from the direction of its pole, producing the overly large radius estimate.

The local surface gravity at the poles is greater than at the equator, which produces a variation in effective temperature over the star: the polar temperature is near 10,000 K, while the equatorial temperature is about 8,152 K.[11] This large temperature difference between the poles and the equator produces a strong gravity darkening effect. As viewed from the poles, this results in a darker (lower-intensity) limb than would normally be expected for a spherically symmetric star. The temperature gradient may also mean that Vega has a convection zone around the equator,[12][72] while the remainder of the atmosphere is likely to be in almost pure radiative equilibrium.[73] By the Von Zeipel theorem, the local luminosity is higher at the poles. As a result, if Vega were viewed along the plane of its equator instead of almost pole-on, then its overall brightness would be lower.

As Vega had long been used as a standard star for calibrating telescopes, the discovery that it is rapidly rotating may challenge some of the underlying assumptions that were based on it being spherically symmetric. With the viewing angle and rotation rate of Vega now better known, this will allow improved instrument calibrations.[74]

Element abundance Edit

In astronomy, those elements with higher atomic numbers than helium are termed "metals". The metallicity of Vega's photosphere is only about 32% of the abundance of heavy elements in the Sun's atmosphere.[note 3] (Compare this, for example, to a threefold metallicity abundance in the similar star Sirius as compared to the Sun.) For comparison, the Sun has an abundance of elements heavier than helium of about ZSol = 0.0172±0.002.[75] Thus, in terms of abundances, only about 0.54% of Vega consists of elements heavier than helium. Nitrogen is slightly more abundant, oxygen is only marginally less abundant and sulfur abundance is about 50% of solar. On the other hand, Vega has only 10% to 30% of the solar abundance for most other major elements with barium and scandium below 10%.[11]

The unusually low metallicity of Vega makes it a weak Lambda Boötis star.[76][77] However, the reason for the existence of such chemically peculiar, spectral class A0–F0 stars remains unclear. One possibility is that the chemical peculiarity may be the result of diffusion or mass loss, although stellar models show that this would normally only occur near the end of a star's hydrogen-burning lifespan. Another possibility is that the star formed from an interstellar medium of gas and dust that was unusually metal-poor.[78]

The observed helium to hydrogen ratio in Vega is 0.030±0.005, which is about 40% lower than the Sun. This may be caused by the disappearance of a helium convection zone near the surface. Energy transfer is instead performed by the radiative process, which may be causing an abundance anomaly through diffusion.[79]

Kinematics Edit

The radial velocity of Vega is the component of this star's motion along the line-of-sight to the Earth. Movement away from the Earth will cause the light from Vega to shift to a lower frequency (toward the red), or to a higher frequency (toward the blue) if the motion is toward the Earth. Thus the velocity can be measured from the amount of shift of the star's spectrum. Precise measurements of this blueshift give a value of −13.9±0.9 km/s.[9] The minus sign indicates a relative motion toward the Earth.

Motion transverse to the line of sight causes the position of Vega to shift with respect to the more distant background stars. Careful measurement of the star's position allows this angular movement, known as proper motion, to be calculated. Vega's proper motion is 202.03±0.63 milliarcseconds (mas) per year in right ascension—the celestial equivalent of longitude—and 287.47±0.54 mas/y in declination, which is equivalent to a change in latitude. The net proper motion of Vega is 327.78 mas/y,[80] which results in angular movement of a degree every 11,000 years.

In the galactic coordinate system, the space velocity components of Vega are (U, V, W) = (−16.1±0.3, −6.3±0.8, −7.7±0.3) km/s, for a net space velocity of 19 km/s.[81] The radial component of this velocity—in the direction of the Sun—is −13.9 km/s, while the transverse velocity is 9.9 km/s. Although Vega is at present only the fifth-brightest star in the night sky, the star is slowly brightening as proper motion causes it to approach the Sun.[82] Vega will make its closest approach in an estimated 264,000 years at a perihelion distance of 13.2 ly (4.04 pc).[83]

Based on this star's kinematic properties, it appears to belong to a stellar association called the Castor Moving Group. However, Vega may be much older than this group, so the membership remains uncertain.[11] This group contains about 16 stars, including Alpha Librae, Alpha Cephei, Castor, Fomalhaut and Vega. All members of the group are moving in nearly the same direction with similar space velocities. Membership in a moving group implies a common origin for these stars in an open cluster that has since become gravitationally unbound.[84] The estimated age of this moving group is 200±100 million years, and they have an average space velocity of 16.5 km/s.[note 4][81]

Possible planetary system Edit

The Vega planetary system[25]
Companion
(in order from star) 		Mass Semimajor axis
(AU) 		Orbital period
(days) 		Eccentricity Inclination Radius
b (unconfirmed) ≥21.9±5.1 M🜨 0.04555±0.00053 2.42977±0.00016 0.25±0.15
Debris disk 86–815 AU 6.2?°
 
A mid-infrared (24 μm) image of the debris disk around Vega

Infrared excess Edit

One of the early results from the Infrared Astronomy Satellite (IRAS) was the discovery of excess infrared flux coming from Vega, beyond what would be expected from the star alone. This excess was measured at wavelengths of 25, 60 and 100 μm, and came from within an angular radius of 10 arcseconds (10″) centered on the star. At the measured distance of Vega, this corresponded to an actual radius of 80 astronomical units (AU), where an AU is the average radius of the Earth's orbit around the Sun. It was proposed that this radiation came from a field of orbiting particles with a dimension on the order of a millimetre, as anything smaller would eventually be removed from the system by radiation pressure or drawn into the star by means of Poynting–Robertson drag.[85] The latter is the result of radiation pressure creating an effective force that opposes the orbital motion of a dust particle, causing it to spiral inward. This effect is most pronounced for tiny particles that are closer to the star.[86]

Subsequent measurements of Vega at 193 μm showed a lower than expected flux for the hypothesized particles, suggesting that they must instead be on the order of 100 μm or less. To maintain this amount of dust in orbit around Vega, a continual source of replenishment would be required. A proposed mechanism for maintaining the dust was a disk of coalesced bodies that were in the process of collapsing to form a planet.[85] Models fitted to the dust distribution around Vega indicate that it is a 120-astronomical-unit-radius circular disk viewed from nearly pole-on. In addition, there is a hole in the center of the disk with a radius of no less than 80 AU.[87]

Following the discovery of an infrared excess around Vega, other stars have been found that display a similar anomaly that is attributable to dust emission. As of 2002, about 400 of these stars have been found, and they have come to be termed "Vega-like" or "Vega-excess" stars. It is believed that these may provide clues to the origin of the Solar System.[24]

Debris disks Edit

By 2005, the Spitzer Space Telescope had produced high-resolution infrared images of the dust around Vega. It was shown to extend out to 43″ (330 AU) at a wavelength of 24 μm, 70″ (543 AU) at 70 μm and 105″ (815 AU) at 160 μm. These much wider disks were found to be circular and free of clumps, with dust particles ranging from 1–50 μm in size. The estimated total mass of this dust is 3×10−3 times the mass of the Earth (around 7.5 times more massive than the asteroid belt). Production of the dust would require collisions between asteroids in a population corresponding to the Kuiper Belt around the Sun. Thus the dust is more likely created by a debris disk around Vega, rather than from a protoplanetary disk as was earlier thought.[23]

 
Artist's concept of a recent massive collision of dwarf planet-sized objects that may have contributed to the dust ring around Vega

The inner boundary of the debris disk was estimated at 11″±2″, or 70–100 AU. The disk of dust is produced as radiation pressure from Vega pushes debris from collisions of larger objects outward. However, continuous production of the amount of dust observed over the course of Vega's lifetime would require an enormous starting mass—estimated as hundreds of times the mass of Jupiter. Hence it is more likely to have been produced as the result of a relatively recent breakup of a moderate-sized (or larger) comet or asteroid, which then further fragmented as the result of collisions between the smaller components and other bodies. This dusty disk would be relatively young on the time scale of the star's age, and it will eventually be removed unless other collision events supply more dust.[23]

Observations, first with the Palomar Testbed Interferometer by David Ciardi and Gerard van Belle in 2001[88] and then later confirmed with the CHARA array at Mt. Wilson in 2006 and the Infrared Optical Telescope Array at Mt. Hopkins in 2011,[89] revealed evidence for an inner dust band around Vega. Originating within 8 AU of the star, this exozodiacal dust may be evidence of dynamical perturbations within the system.[90] This may be caused by an intense bombardment of comets or meteors, and may be evidence for the existence of a planetary system.[91]

Possible planets Edit

Observations from the James Clerk Maxwell Telescope in 1997 revealed an "elongated bright central region" that peaked at 9″ (70 AU) to the northeast of Vega. This was hypothesized as either a perturbation of the dust disk by a planet or else an orbiting object that was surrounded by dust. However, images by the Keck telescope had ruled out a companion down to magnitude 16, which would correspond to a body with more than 12 times the mass of Jupiter.[92] Astronomers at the Joint Astronomy Centre in Hawaii and at UCLA suggested that the image may indicate a planetary system still undergoing formation.[93]

Determining the nature of the planet has not been straightforward; a 2002 paper hypothesizes that the clumps are caused by a roughly Jupiter-mass planet on an eccentric orbit. Dust would collect in orbits that have mean-motion resonances with this planet—where their orbital periods form integer fractions with the period of the planet—producing the resulting clumpiness.[94]

 
Artist's impression of a planet around Vega

In 2003, it was hypothesized that these clumps could be caused by a roughly Neptune-mass planet having migrated from 40 to 65 AU over 56 million years,[95] an orbit large enough to allow the formation of smaller rocky planets closer to Vega. The migration of this planet would likely require gravitational interaction with a second, higher-mass planet in a smaller orbit.[96]

Using a coronagraph on the Subaru Telescope in Hawaii in 2005, astronomers were able to further constrain the size of a planet orbiting Vega to no more than 5–10 times the mass of Jupiter.[97] The issue of possible clumps in the debris disc was revisited in 2007 using newer, more sensitive instrumentation on the Plateau de Bure Interferometer. The observations showed that the debris ring is smooth and symmetric. No evidence was found of the blobs reported earlier, casting doubts on the hypothesized giant planet.[98] The smooth structure has been confirmed in follow-up observations by Hughes et al. (2012)[99] and the Herschel Space Telescope.[100]

Although a planet has yet to be directly observed around Vega, the presence of a planetary system cannot yet be ruled out. Thus there could be smaller, terrestrial planets orbiting closer to the star. The inclination of planetary orbits around Vega is likely to be closely aligned to the equatorial plane of this star.[101]

From the perspective of an observer on a hypothetical planet around Vega, the Sun would appear as a faint 4.3-magnitude star in the Columba constellation.[note 5]

In 2021, a paper analyzing 10 years of spectra of Vega detected a candidate 2.43-day signal around Vega, statistically estimated to have only a 1% chance of being a false positive.[25] Considering the amplitude of the signal, the authors estimated a minimum mass of 21.9±5.1 Earth masses, but considering the very oblique rotation of Vega itself of only 6.2° from Earth's perspective, the planet may be aligned to this plane as well, giving it an actual mass of 203±47 Earth masses.[25] The researchers also detected a faint 196.4+1.6
−1.9-day signal which could translate to a 80±21 Earth masses (740±190 at 6.2° inclination) but is too faint to claim as a real signal with available data.[25]

Etymology and cultural significance Edit

See also: Summer Triangle, Stars in astrology § Vega, and Vega in fiction

The name is believed to be derived from the Arabic term Al Nesr al Waki النسر الواقع which appeared in the Al Achsasi al Mouakket star catalogue and was translated into Latin as Vultur Cadens, "the falling eagle/vulture".[102][note 6] The constellation was represented as a vulture in ancient Egypt,[103] and as an eagle or vulture in ancient India.[104][105] The Arabic name then appeared in the western world in the Alfonsine tables,[106] which were drawn up between 1215 and 1270 by order of King Alfonso X.[107] Medieval astrolabes of England and Western Europe used the names Wega and Alvaca, and depicted it and Altair as birds.[108]

Among the northern Polynesian people, Vega was known as whetu o te tau, the year star. For a period of history it marked the start of their new year when the ground would be prepared for planting. Eventually this function became denoted by the Pleiades.[109]

The Assyrians named this pole star Dayan-same, the "Judge of Heaven", while in Akkadian it was Tir-anna, "Life of Heaven". In Babylonian astronomy, Vega may have been one of the stars named Dilgan, "the Messenger of Light". To the ancient Greeks, the constellation Lyra was formed from the harp of Orpheus, with Vega as its handle.[16] For the Roman Empire, the start of autumn was based upon the hour at which Vega set below the horizon.[15]

In Chinese, 織女 (Zhī Nǚ), meaning Weaving Girl (asterism), refers to an asterism consisting of Vega, ε Lyrae and ζ1 Lyrae.[110] Consequently, the Chinese name for Vega is 織女一 (Zhī Nǚ yī, English: the First Star of Weaving Girl).[111] In Chinese mythology, there is a love story of Qixi (七夕) in which Niulang (牛郎, Altair) and his two children (β Aquilae and γ Aquilae) are separated from their mother Zhinü (織女, lit. "weaver girl", Vega) who is on the far side of the river, the Milky Way.[112] However, one day per year on the seventh day of the seventh month of the Chinese lunisolar calendar, magpies make a bridge so that Niulang and Zhinü can be together again for a brief encounter. The Japanese Tanabata festival, in which Vega is known as Orihime (織姫), is also based on this legend.[113]

In Zoroastrianism, Vega was sometimes associated with Vanant, a minor divinity whose name means "conqueror".[114]

The indigenous Boorong people of northwestern Victoria, Australia, named it as Neilloan,[115] "the flying loan".[116]

In the Srimad Bhagavatam, Shri Krishna tells Arjuna, that among the Nakshatras he is Abhijit, which remark indicates the auspiciousness of this Nakshatra.[117]

Medieval astrologers counted Vega as one of the Behenian stars[118] and related it to chrysolite and winter savory. Cornelius Agrippa listed its kabbalistic sign   under Vultur cadens, a literal Latin translation of the Arabic name.[119] Medieval star charts also listed the alternate names Waghi, Vagieh and Veka for this star.[31]

W. H. Auden's 1933 poem "A Summer Night (to Geoffrey Hoyland)"[120] famously opens with the couplet, "Out on the lawn I lie in bed,/Vega conspicuous overhead".

Vega became the first star to have a car named after it with the French Facel Vega line of cars from 1954 onwards, and later on, in America, Chevrolet launched the Vega in 1971.[121] Other vehicles named after Vega include the ESA's Vega launch system[122] and the Lockheed Vega aircraft.[123]

Notes Edit

  1. ^ The polar temperature is around 2,000 K higher than at the equator due to the rapid rotation of Vega
  2. ^ From Cox, Arthur N., ed. (1999). Allen's Astrophysical Qualities (4th ed.). New York: Springer-Verlag. p. 382. ISBN 978-0-387-98746-0.:
    Mbol = −2.5 log L/L + 4.74,
    where Mbol is the bolometric magnitude, L is the star's luminosity, and L is the solar luminosity. A Mbol variation of ±0.03 gives
    Mbol2Mbol1 = 0.03 = 2.5 log L1/L2
    for
    L1/L2 = 100.03/2.5 ≈ 1.028,
    or a ±2.8% luminosity variation.
  3. ^ For a metallicity of −0.5, the proportion of metals relative to the Sun is given by
     .
    See: Matteucci, Francesca (2001). The Chemical Evolution of the Galaxy. Astrophysics and Space Science Library. Vol. 253. Springer Science & Business Media. p. 7. ISBN 978-0792365525.
  4. ^ The space velocity components in the Galactic coordinate system are: U = −10.7±3.5, V = −8.0±2.4, W = −9.7±3.0 km/s. UVW is a Cartesian coordinate system, so the Euclidean distance formula applies. Hence, the net velocity is
     
    See: Bruce, Peter C. (2015). Introductory Statistics and Analytics: A Resampling Perspective. John Wiley & Sons. p. 20. ISBN 978-1118881330.
  5. ^ The Sun would appear at the diametrically opposite coordinates from Vega at α = 6h 36m 56.3364s, δ = −38° 47′ 01.291″, which is in the western part of Columba.

    The visual magnitude is given by  π [original research?]
    See: Hughes, David W. (2006). "The Introduction of Absolute Magnitude (1902–1922)". Journal of Astronomical History and Heritage. 9 (2): 173–179. Bibcode:2006JAHH....9..173H.
  6. ^ That is, a vulture on the ground with its wings folded (Edward William Lane, Arabic-English Lexicon).

References Edit

  1. ^ "Vega". Oxford English Dictionary (Online ed.). Oxford University Press. (Subscription or participating institution membership required.)
  2. ^ a b "Vega". Merriam-Webster Dictionary.
  3. ^ Kunitzsch, Paul; Smart, Tim (2006). A Dictionary of Modern star Names: A Short Guide to 254 Star Names and Their Derivations (2nd rev. ed.). Cambridge, Massachusetts: Sky Pub. ISBN 978-1-931559-44-7.
  4. ^ a b c d e f van Leeuwen, F. (November 2007). "Validation of the new Hipparcos reduction". Astronomy and Astrophysics. 474 (2): 653–664. arXiv:0708.1752. Bibcode:2007A&A...474..653V. doi:10.1051/0004-6361:20078357. S2CID 18759600.
  5. ^ Bohlin, R. C.; Gilliland, R. L. (2004). "Hubble Space Telescope Absolute Spectrophotometry of Vega from the Far-Ultraviolet to the Infrared". The Astronomical Journal. 127 (6): 3508–3515. Bibcode:2004AJ....127.3508B. doi:10.1086/420715.
  6. ^ a b Samus, N. N.; Durlevich, O. V.; et al. (2009). "VizieR Online Data Catalog: General Catalogue of Variable Stars (Samus+ 2007–2013)". VizieR On-line Data Catalog: B/GCVS. Originally Published in: 2009yCat....102025S. 1: 02025. Bibcode:2009yCat....102025S.
  7. ^ Gray, R. O.; Corbally, C. J.; Garrison, R. F.; McFadden, M. T.; Robinson, P. E. (2003). "Contributions to the Nearby Stars (NStars) Project: Spectroscopy of Stars Earlier than M0 within 40 parsecs: The Northern Sample I". The Astronomical Journal. 126 (4): 2048. arXiv:astro-ph/0308182. Bibcode:2003AJ....126.2048G. doi:10.1086/378365. S2CID 119417105.
  8. ^ a b Ducati, J. R. (2002). "VizieR Online Data Catalog: Catalogue of Stellar Photometry in Johnson's 11-color system". CDS/ADC Collection of Electronic Catalogues. 2237. Bibcode:2002yCat.2237....0D.
  9. ^ a b Evans, D. S. (June 20–24, 1966). "The Revision of the General Catalogue of Radial Velocities". Proceedings from IAU Symposium no. 30. Determination of Radial Velocities and Their Applications. Vol. 30. London, England. p. 57. Bibcode:1967IAUS...30...57E.
  10. ^ Gatewood, George (2008). "Astrometric Studies of Aldebaran, Arcturus, Vega, the Hyades, and Other Regions". The Astronomical Journal. 136 (1): 452–460. Bibcode:2008AJ....136..452G. doi:10.1088/0004-6256/136/1/452.
  11. ^ a b c d e f g h i j k l m Yoon, Jinmi; et al. (January 2010). "A New View of Vega's Composition, Mass, and Age". The Astrophysical Journal. 708 (1): 71–79. Bibcode:2010ApJ...708...71Y. doi:10.1088/0004-637X/708/1/71.
  12. ^ a b c d Aufdenberg, J.P.; et al. (2006). "First results from the CHARA Array: VII. Long-Baseline Interferometric Measurements of Vega Consistent with a Pole-On, Rapidly Rotating Star?". Astrophysical Journal. 645 (1): 664–675. arXiv:astro-ph/0603327. Bibcode:2006ApJ...645..664A. doi:10.1086/504149. S2CID 13501650.
  13. ^ a b c Kinman, T.; et al. (2002). "The determination of Teff for metal-poor A-type stars using V and 2MASS J, H and K magnitudes". Astronomy and Astrophysics. 391 (3): 1039–1052. Bibcode:2002A&A...391.1039K. doi:10.1051/0004-6361:20020806.
  14. ^ a b c Petit, P.; Böhm, T.; Folsom, C. P.; Lignières, F.; Cang, T. (2022). "A decade-long magnetic monitoring of Vega". Astronomy and Astrophysics. 666: A20. arXiv:2208.09196. Bibcode:2022A&A...666A..20P. doi:10.1051/0004-6361/202143000. S2CID 251710497.
  15. ^ a b c d e Allen, Richard Hinckley (1963). Star Names: Their Lore and Meaning. Courier Dover Publications. ISBN 978-0-486-21079-7.
  16. ^ a b Kendall, E. Otis (1845). Uranography: Or, A Description of the Heavens; Designed for Academics and Schools; Accompanied by an Atlas of the Heavens. Philadelphia: Oxford University Press.
  17. ^ Staff. "V* alf Lyr – Variable Star". SIMBAD. Retrieved October 30, 2007.—use the "display all measurements" option to show additional parameters.
  18. ^ Gulliver, Austin F.; et al. (1994). "Vega: A rapidly rotating pole-on star". The Astrophysical Journal. 429 (2): L81–L84. Bibcode:1994ApJ...429L..81G. doi:10.1086/187418.
  19. ^ "Calculation by the Stellarium application version 0.10.2". Retrieved July 28, 2009.
  20. ^ a b Barger, M. Susan; et al. (2000) [First published 1991]. The Daguerreotype: Nineteenth-Century Technology and Modern Science. JHU Press. p. 88. ISBN 978-0-8018-6458-2.
  21. ^ a b Barker, George F. (1887). "On the Henry Draper Memorial Photographs of Stellar Spectra". Proceedings of the American Philosophical Society. 24: 166–172.
  22. ^ a b Peterson, D. M.; et al. (2006). "Vega is a rapidly rotating star". Nature. 440 (7086): 896–899. arXiv:astro-ph/0603520. Bibcode:2006Natur.440..896P. doi:10.1038/nature04661. PMID 16612375. S2CID 533664.
  23. ^ a b c Su, K. Y. L.; et al. (2005). "The Vega Debris Disk: A Surprise from Spitzer". The Astrophysical Journal. 628 (1): 487–500. arXiv:astro-ph/0504086. Bibcode:2005ApJ...628..487S. doi:10.1086/430819. S2CID 18898968.
  24. ^ a b Song, Inseok; et al. (2002). "M-Type Vega-like Stars". The Astronomical Journal. 124 (1): 514–518. arXiv:astro-ph/0204255. Bibcode:2002AJ....124..514S. doi:10.1086/341164. S2CID 3450920.
  25. ^ a b c d e Hurt, Spencer A.; Quinn, Samuel N.; Latham, David W.; Vanderburg, Andrew; Esquerdo, Gilbert A.; Calkins, Michael L.; Berlind, Perry; Angus, Ruth; Latham, Christian A.; Zhou, George (January 21, 2021). "A Decade of Radial-velocity Monitoring of Vega and New Limits on the Presence of Planets". The Astronomical Journal. 161 (4): 157. arXiv:2101.08801. Bibcode:2021AJ....161..157H. doi:10.3847/1538-3881/abdec8. S2CID 231693198.
  26. ^ Glassé, Cyril (2008). The new encyclopedia of Islam. Reference, Information and Interdisciplinary Subjects Series (3rd ed.). Rowman & Littlefield. p. 75. ISBN 978-0-7425-6296-7.
  27. ^ "IAU Working Group on Star Names (WGSN)". International Astronomical Union. Retrieved May 22, 2016.
  28. ^ "Bulletin of the IAU Working Group on Star Names, No. 1" (PDF). IAU Division C: Education, Outreach and Heritage (WGSN). July 2016. Retrieved July 28, 2016.
  29. ^ "IAU Catalog of Star Names". IAU Division C: Education, Outreach and Heritage (WGSN). August 21, 2016. Retrieved July 28, 2016.
  30. ^ a b Pasachoff, Jay M. (2000). A Field Guide to Stars and Planets (4th ed.). Houghton Mifflin Field Guides. ISBN 978-0-395-93431-9.
  31. ^ a b Burnham, Robert J. R. (1978). Burnham's Celestial Handbook: An Observer's Guide to the Universe Beyond the Solar System. Vol. 2. Courier Dover Publications. ISBN 978-0-486-23568-4.
  32. ^ Chaikin, Andrew L. (1990). Beatty, J. K.; Petersen, C. C. (eds.). The New Solar System (4th ed.). Cambridge, England: Cambridge University Press. ISBN 978-0-521-64587-4.
  33. ^ Roy, Archie E.; et al. (2003). Astronomy: Principles and Practice. CRC Press. ISBN 978-0-7503-0917-2.
  34. ^ a b Tomkin, Jocelyn (April 1998). "Once and Future Celestial Kings". Sky and Telescope. 95 (4): 59–63. Bibcode:1998S&T....95d..59T. – based on computations from HIPPARCOS data. (The calculations exclude stars whose distance or proper motion is uncertain.) PDF[permanent dead link]
  35. ^ Upgren, Arthur R. (1998). Night Has a Thousand Eyes: A Naked-Eye Guide to the Sky, Its Science, and Lore. Basic Books. Bibcode:1998nhte.book.....U. ISBN 978-0-306-45790-6.
  36. ^ Holden, Edward S.; et al. (1890). "Photographs of Venus, Mercury and Alpha Lyræ in Daylight". Publications of the Astronomical Society of the Pacific. 2 (10): 249–250. Bibcode:1890PASP....2..249H. doi:10.1086/120156. S2CID 120286863.
  37. ^ "Spectroscopy and the Birth of Astrophysics". Tools of Cosmology. American Institute of Physics. Retrieved March 29, 2022.
  38. ^ Hentschel, Klaus (2002). Mapping the Spectrum: Techniques of Visual Representation in Research and Teaching. Oxford University Press. ISBN 978-0-19-850953-0.
  39. ^ Garrison, R. F. (December 1993). . Bulletin of the American Astronomical Society. 25: 1319. Bibcode:1993AAS...183.1710G. Archived from the original on June 25, 2019. Retrieved February 5, 2012.
  40. ^ Berry, Arthur (1899). A Short History of Astronomy. New York: Charles Scribner's Sons. ISBN 978-0-486-20210-5.
  41. ^ Dick, Wolfgang R.; Ruben, G. (1988). "The First Successful Attempts to Determine Stellar Parallaxes in the Light of the Bessel/Struve Correspondence". Mapping the Sky: Past Heritage and Future Directions. Springer. pp. 119–121. doi:10.1017/S007418090013949X. ISBN 978-90-277-2810-4.
  42. ^ Anonymous (June 28, 2007). "The First Parallax Measurements". Astroprof. Retrieved November 12, 2007.
  43. ^ Perryman, M. A. C.; et al. (1997). "The Hipparcos Catalogue". Astronomy and Astrophysics. 323: L49–L52. Bibcode:1997A&A...323L..49P.
  44. ^ Perryman, Michael (2010). The Making of History's Greatest Star Map. Astronomers' Universe. Heidelberg: Springer-Verlag. Bibcode:2010mhgs.book.....P. doi:10.1007/978-3-642-11602-5. ISBN 978-3-642-11601-8.
  45. ^ Garfinkle, Robert A. (1997). Star-Hopping: Your Visa to Viewing the Universe. Cambridge University Press. ISBN 978-0-521-59889-7.
  46. ^ Cochran, A. L. (1981). "Spectrophotometry with a self-scanned silicon photodiode array. II – Secondary standard stars". Astrophysical Journal Supplement Series. 45: 83–96. Bibcode:1981ApJS...45...83C. doi:10.1086/190708.
  47. ^ Johnson, H. L.; et al. (1953). "Fundamental stellar photometry for standards of spectral type on the revised system of the Yerkes spectral atlas". Astrophysical Journal. 117: 313–352. Bibcode:1953ApJ...117..313J. doi:10.1086/145697.
  48. ^ Walsh, J. (March 6, 2002). . Optical and UV Spectrophotometric Standard Stars. ESO. Archived from the original on February 9, 2007. Retrieved November 15, 2007.—flux versus wavelength for Vega.
  49. ^ McMahon, Richard G. (November 23, 2005). "Notes on Vega and magnitudes" (Text). University of Cambridge. Retrieved November 7, 2007.
  50. ^ a b Fernie, J. D. (1981). "On the variability of Vega". Publications of the Astronomical Society of the Pacific. 93 (2): 333–337. Bibcode:1981PASP...93..333F. doi:10.1086/130834.
  51. ^ Gautschy, A.; et al. (1995). "Stellar Pulsations Across The HR Diagram: Part 1". Annual Review of Astronomy and Astrophysics. 33 (1): 75–114. Bibcode:1995ARA&A..33...75G. doi:10.1146/annurev.aa.33.090195.000451.
  52. ^ I.A., Vasil'yev; et al. (March 17, 1989). "On the Variability of Vega". Commission 27 of the I.A.U. Retrieved October 30, 2007.
  53. ^ Hayes, D. S. (May 24–29, 1984). "Stellar absolute fluxes and energy distributions from 0.32 to 4.0 microns". Proceedings of the Symposium, Calibration of fundamental stellar quantities. Calibration of Fundamental Stellar Quantities. Vol. 111. pp. 225–252. Bibcode:1985IAUS..111..225H.
  54. ^ Gray, Raymond (2007). "The Problems with Vega". The Future of Photometric, Spectrophotometric and Polarimetric Standardization, ASP Conference Series, Proceedings of a Conference Held 8–11 May 2006 in Blankenberge, Belgium. 364: 305–. Bibcode:2007ASPC..364..305G.
  55. ^ Butkovskaya, Varvara (2011). "The long-term variability of Vega". Astronomische Nachrichten. 332 (9–10): 956–960. Bibcode:2011AN....332..956B. doi:10.1002/asna.201111587.
  56. ^ a b c Topka, K.; et al. (1979). "Detection of soft X-rays from Alpha Lyrae and Eta Bootis with an imaging X-ray telescope". Astrophysical Journal. 229: 661. Bibcode:1979ApJ...229..661T. doi:10.1086/157000.
  57. ^ Harvey, Paul E.; et al. (1984). "On the far-infrared excess of Vega". Nature. 307 (5950): 441–442. Bibcode:1984Natur.307..441H. doi:10.1038/307441a0. S2CID 4330793.
  58. ^ Mengel, J. G.; et al. (1979). "Stellar evolution from the zero-age main sequence". Astrophysical Journal Supplement Series. 40: 733–791. Bibcode:1979ApJS...40..733M. doi:10.1086/190603.—From pages 769–778: for stars in the range 1.75 < M < 2.2, 0.2 < Y < 0.3 and 0.004 < Z < 0.01, stellar models give an age range of (0.43–1.64)×109 years between a star joining the main sequence and turning off to the red giant branch. With a mass closer to 2.2, however, the interpolated age for Vega is less than a billion.
  59. ^ Salaris, Maurizio; et al. (2005). Evolution of Stars and Stellar Populations. John Wiley and Sons. p. 120. ISBN 978-0-470-09220-0.
  60. ^ Browning, Matthew; et al. (2004). "Simulations of core convection in rotating A-type stars: Differential rotation and overshooting". Astrophysical Journal. 601 (1): 512–529. arXiv:astro-ph/0310003. Bibcode:2004ApJ...601..512B. doi:10.1086/380198. S2CID 16201995.
  61. ^ Padmanabhan, Thanu (2002). Theoretical Astrophysics. Cambridge University Press. ISBN 978-0-521-56241-6.
  62. ^ Oke, J. B.; et al. (1970). "The Absolute Spectral Energy Distribution of Alpha Lyrae". Astrophysical Journal. 161: 1015–1023. Bibcode:1970ApJ...161.1015O. doi:10.1086/150603.
  63. ^ Richmond, Michael. "The Boltzmann Equation". Rochester Institute of Technology. Retrieved November 15, 2007.
  64. ^ Clayton, Donald D. (1983). Principles of Stellar Evolution and Nucleosynthesis. University of Chicago Press. ISBN 978-0-226-10953-4.
  65. ^ Michelson, E. (1981). "The near ultraviolet stellar spectra of alpha Lyrae and beta Orionis". Monthly Notices of the Royal Astronomical Society. 197: 57–74. Bibcode:1981MNRAS.197...57M. doi:10.1093/mnras/197.1.57.
  66. ^ Schmitt, J. H. M. M. (1999). "Coronae on solar-like stars". Astronomy and Astrophysics. 318: 215–230. Bibcode:1997A&A...318..215S.
  67. ^ a b Vaiana, G. S. (1980). A. K. Dupree (ed.). "Stellar Coronae – Overview of the Einstein / CFA Stellar Survey In: Cool Stars, Stellar Systems, and the Sun". SAO Special Report. 389 (389): 195–215. Bibcode:1980SAOSR.389..195V.
  68. ^ Munro, R. H.; et al. (May 1977). "Physical properties of a polar coronal hole from 2 to 5 solar radii". Astrophysical Journal. 213 (5): 874–86. Bibcode:1977ApJ...213..874M. doi:10.1086/155220.
  69. ^ Lignières, F.; et al. (2009). "First evidence of a magnetic field on Vega". Astronomy & Astrophysics. 500 (3): L41–L44. arXiv:0903.1247. Bibcode:2009A&A...500L..41L. doi:10.1051/0004-6361/200911996. S2CID 6021105.
  70. ^ Staff (July 26, 2009). "Magnetic Field On Bright Star Vega". Science Daily. Retrieved July 30, 2009.
  71. ^ Böhm, T.; et al. (May 2015). "Discovery of starspots on Vega. First spectroscopic detection of surface structures on a normal A-type star". Astronomy & Astrophysics. 577: 12. arXiv:1411.7789. Bibcode:2015A&A...577A..64B. doi:10.1051/0004-6361/201425425. S2CID 53548120. A64.
  72. ^ Staff (January 10, 2006). "Rapidly Spinning Star Vega has Cool Dark Equator". National Optical Astronomy Observatory. Retrieved November 18, 2007.
  73. ^ Adelman, Saul J. (July 2004). "The physical properties of normal A stars". Proceedings of the International Astronomical Union. 2004 (IAUS224): 1–11. Bibcode:2004IAUS..224....1A. doi:10.1017/S1743921304004314.
  74. ^ Quirrenbach, Andreas (2007). "Seeing the Surfaces of Stars". Science. 317 (5836): 325–326. doi:10.1126/science.1145599. PMID 17641185. S2CID 118213499.
  75. ^ Antia, H. M.; et al. (2006). "Determining Solar Abundances Using Helioseismology". The Astrophysical Journal. 644 (2): 1292–1298. arXiv:astro-ph/0603001. Bibcode:2006ApJ...644.1292A. doi:10.1086/503707. S2CID 15334093.
  76. ^ Renson, P.; et al. (1990). "Catalogue of Lambda Bootis Candidates". Bulletin d'Information du Centre de Données Stellaires. 38: 137–149. Bibcode:1990BICDS..38..137R.—Entry for HD 172167 on p. 144.
  77. ^ Qiu, H. M.; et al. (2001). "The Abundance Patterns of Sirius and Vega". The Astrophysical Journal. 548 (2): 77–115. Bibcode:2001ApJ...548..953Q. doi:10.1086/319000.
  78. ^ Martinez, Peter; et al. (1998). "The pulsating lambda Bootis star HD 105759". Monthly Notices of the Royal Astronomical Society. 301 (4): 1099–1103. Bibcode:1998MNRAS.301.1099M. doi:10.1046/j.1365-8711.1998.02070.x.
  79. ^ Adelman, Saul J.; et al. (1990). "An elemental abundance analysis of the superficially normal A star Vega". Astrophysical Journal, Part 1. 348: 712–717. Bibcode:1990ApJ...348..712A. doi:10.1086/168279.
  80. ^ Majewski, Steven R. (2006). "Stellar Motions". University of Virginia. Archived from the original on January 25, 2012. Retrieved September 27, 2007.—The net proper motion is given by:
     
    where   and   are the components of proper motion in the R.A. and Declination, respectively, and   is the Declination.
  81. ^ a b Barrado y Navascues, D. (1998). "The Castor moving group. The age of Fomalhaut and VEGA". Astronomy and Astrophysics. 339: 831–839. arXiv:astro-ph/9905243. Bibcode:1998A&A...339..831B.
  82. ^ Moulton, Forest Ray (1906). An Introduction to Astronomy. The Macmillan company. p. 502.
  83. ^ Bailer-Jones, C. A. L. (March 2015). "Close encounters of the stellar kind". Astronomy & Astrophysics. 575: 13. arXiv:1412.3648. Bibcode:2015A&A...575A..35B. doi:10.1051/0004-6361/201425221. S2CID 59039482. A35.
  84. ^ Inglis, Mike (2003). Observer's Guide to Stellar Evolution: The Birth, Life, and Death of Stars. Springer. ISBN 978-1-85233-465-9.
  85. ^ a b Harper, D. A.; et al. (1984). "On the nature of the material surrounding VEGA". Astrophysical Journal, Part 1. 285: 808–812. Bibcode:1984ApJ...285..808H. doi:10.1086/162559.
  86. ^ Robertson, H. P. (April 1937). "Dynamical effects of radiation in the solar system". Monthly Notices of the Royal Astronomical Society. 97 (6): 423–438. Bibcode:1937MNRAS..97..423R. doi:10.1093/mnras/97.6.423.
  87. ^ Dent, W. R. F.; et al. (2000). "Models of the dust structures around Vega-excess stars". Monthly Notices of the Royal Astronomical Society. 314 (4): 702–712. Bibcode:2000MNRAS.314..702D. doi:10.1046/j.1365-8711.2000.03331.x.
  88. ^ Ciardi, David R.; et al. (2001). "On The Near-Infrared Size of Vega". The Astrophysical Journal. 559 (1): 237–244. arXiv:astro-ph/0105561. Bibcode:2001ApJ...559.1147C. doi:10.1086/322345. S2CID 15898697.
  89. ^ Defrère, D.; et al. (2011). "Hot exozodiacal dust resolved around Vega with IOTA/IONIC". Astronomy and Astrophysics. 534: A5. arXiv:1108.3698. Bibcode:2011A&A...534A...5D. doi:10.1051/0004-6361/201117017. S2CID 8291382.
  90. ^ Absil, O.; et al. (2006). "Circumstellar material in the Vega inner system revealed by CHARA/FLUOR". Astronomy and Astrophysics. 452 (1): 237–244. arXiv:astro-ph/0604260. Bibcode:2006A&A...452..237A. doi:10.1051/0004-6361:20054522. S2CID 2165054.
  91. ^ Girault-Rime, Marion (Summer 2006). "Vega's Stardust". CNRS International Magazine. Retrieved November 19, 2007.
  92. ^ Holland, Wayne S.; et al. (1998). "Submillimetre images of dusty debris around nearby stars". Nature. 392 (6678): 788–791. Bibcode:1998Natur.392..788H. doi:10.1038/33874. S2CID 4373502.
  93. ^ Staff (April 21, 1998). . Joint Astronomy Centre. Archived from the original on December 16, 2008. Retrieved October 29, 2007.
  94. ^ Wilner, D.; et al. (2002). "Structure in the Dusty Debris around Vega". The Astrophysical Journal. 569 (2): L115–L119. arXiv:astro-ph/0203264. Bibcode:2002ApJ...569L.115W. doi:10.1086/340691. S2CID 36818074.
  95. ^ Wyatt, M. (2003). "Resonant Trapping of Planetesimals by Planet Migration: Debris Disk Clumps and Vega's Similarity to the Solar System". The Astrophysical Journal. 598 (2): 1321–1340. arXiv:astro-ph/0308253. Bibcode:2003ApJ...598.1321W. doi:10.1086/379064. S2CID 10755059.
  96. ^ Gilchrist, E.; et al. (December 1, 2003). "New evidence for Solar-like planetary system around nearby star". Royal Observatory, Edinburgh. Retrieved October 30, 2007.
  97. ^ Itoh, Yoichi; et al. (2006). "Coronagraphic Search for Extrasolar Planets around ε Eri and Vega". The Astrophysical Journal. 652 (2): 1729–1733. arXiv:astro-ph/0608362. Bibcode:2006ApJ...652.1729I. doi:10.1086/508420. S2CID 119542260.
  98. ^ Piétu, V.; et al. (July 2011). "High-sensitivity search for clumps in the Vega Kuiper-belt. New PdBI 1.3 mm observations". Astronomy & Astrophysics. 531: L2. arXiv:1105.2586. Bibcode:2011A&A...531L...2P. doi:10.1051/0004-6361/201116796. S2CID 55674804.
  99. ^ Hughes, A. Meredith; et al. (2012). "Confirming the Primarily Smooth Structure of the Vega Debris Disk at Millimeter Wavelengths". The Astrophysical Journal. 750 (1): 82. arXiv:1203.0318. Bibcode:2012ApJ...750...82H. doi:10.1088/0004-637X/750/1/82. S2CID 118553890. 82.
  100. ^ Sibthorpe, B.; et al. (2010). "The Vega debris disc: A view from Herschel". Astronomy and Astrophysics. 518: L130. arXiv:1005.3543. Bibcode:2010A&A...518L.130S. doi:10.1051/0004-6361/201014574. S2CID 6461181. L130.
  101. ^ Campbell, B.; et al. (1985). "On the inclination of extra-solar planetary orbits". Publications of the Astronomical Society of the Pacific. 97: 180–182. Bibcode:1985PASP...97..180C. doi:10.1086/131516.
  102. ^ Knobel, E. B. (June 1895). "Al Achsasi Al Mouakket, on a catalogue of stars in the Calendarium of Mohammad Al Achsasi Al Mouakket". Monthly Notices of the Royal Astronomical Society. 55 (8): 429–438. Bibcode:1895MNRAS..55..429K. doi:10.1093/mnras/55.8.429.
  103. ^ Massey, Gerald (2001). Ancient Egypt: the Light of the World. Adamant Media Corporation. ISBN 978-1-60206-086-9.
  104. ^ Olcott, William Tyler (1911). Star Lore of All Ages: A Collection of Myths, Legends, and Facts Concerning the Constellations of the Northern Hemisphere. G.P. Putnam's sons. Bibcode:1911slaa.book.....O. ISBN 978-0-7873-1096-7.
  105. ^ Houlding, Deborah (December 2005). "Lyra: The Lyre". Sktscript. Retrieved November 4, 2007.
  106. ^ Kunitzsch, Paul (1986). "The Star Catalogue Commonly Appended to the Alfonsine Tables". Journal for the History of Astronomy. 17 (49): 89–98. Bibcode:1986JHA....17...89K. doi:10.1177/002182868601700202. S2CID 118597258.
  107. ^ Houtsma, M. Th.; et al. (1987). E. J. Brill's First Encyclopaedia of Islam, 1913–36. Vol. VII. E.J. Brill. p. 292.
  108. ^ Gingerich, O. (1987). "Zoomorphic Astrolabes and the Introduction of Arabic Star Names into Europe". Annals of the New York Academy of Sciences. 500 (1): 89–104. Bibcode:1987NYASA.500...89G. doi:10.1111/j.1749-6632.1987.tb37197.x. S2CID 84102853.
  109. ^ Smith, S. Percy (1919). "The Fatherland of the Polynesians – Aryan and Polynesian Points of Contact". The Journal of the Polynesian Society. 28: 18–20.
  110. ^ 陳久金 (2005). 中國星座神話. 五南圖書出版股份有限公司. ISBN 978-986-7332-25-7.
  111. ^ "天文教育資訊網" [AEEA (Activities of Exhibition and Education in Astronomy)] (in Chinese). July 3, 2006. Retrieved January 6, 2019.
  112. ^ Wei, Liming; et al. (2005). Chinese Festivals. Chinese Intercontinental Press. ISBN 978-7-5085-0836-8.
  113. ^ Kippax, John Robert (1919). The Call of the Stars: A Popular Introduction to a Knowledge of the Starry Skies with their Romance and Legend. G. P. Putnam's Sons.
  114. ^ Boyce, Mary (1996). A History of Zoroastrianism, volume one: The Early Period. New York: E. J. Brill. ISBN 978-90-04-08847-4.
  115. ^ Hamacher, Duane W.; et al. (2010). "An Aboriginal Australian Record of the Great Eruption of Eta Carinae". Journal of Astronomical History & Heritage. 13 (3): 220–34. arXiv:1010.4610. Bibcode:2010JAHH...13..220H. doi:10.3724/SP.J.1440-2807.2010.03.06. S2CID 118454721.
  116. ^ Stanbridge, William Edward (1857). "On the astronomy and mythology of the Aborigines of Victoria". Proceedings of the Philosophical Institute of Victoria. 2: 137. Bibcode:1857PPIVT...2..137S.
  117. ^ "ŚB 11.16.27". vedabase.io. Retrieved March 29, 2021.
  118. ^ Tyson, Donald; et al. (1993). Three Books of Occult Philosophy. Llewellyn Worldwide. ISBN 978-0-87542-832-1.
  119. ^ Agrippa, Heinrich Cornelius (1533). De Occulta Philosophia. ISBN 978-90-04-09421-5.
  120. ^ "W. H. Auden – A Summer Night (to Geoffrey Hoyland)". Retrieved January 6, 2019.
  121. ^ Frommert, Hartmut. "Vega, Alpha Lyrae". SEDS. Archived from the original on October 24, 2007. Retrieved November 2, 2007.
  122. ^ Staff (May 20, 2005). "Launch vehicles – Vega". European Space Agency. Retrieved November 12, 2007.
  123. ^ Rumerman, Judy (2003). . U.S. Centennial of Flight Commission. Archived from the original on October 18, 2007. Retrieved November 12, 2007.

External links Edit

 
Wikimedia Commons has media related to Vega.
  • Anonymous. "Vega". SolStation. The Sol Company. Retrieved November 9, 2005.
  • Gilchrist, Eleanor; et al. (December 1, 2003). . Joint Astronomy Centre. Archived from the original on September 23, 2009. Retrieved November 10, 2007.
  • Hill, Gay Yee; et al. (January 10, 2005). . NASA/Spitzer Space Telescope. Archived from the original on May 18, 2007. Retrieved November 2, 2007.


October 20, 2023
vega, star, redirects, here, psychologist, star, psychologist, other, uses, disambiguation, brightest, star, northern, constellation, lyra, bayer, designation, lyrae, which, latinised, alpha, lyrae, abbreviated, alpha, this, star, relatively, close, only, ligh. Star Vega redirects here For the psychologist see Star Vega psychologist For other uses see Vega disambiguation Vega is the brightest star in the northern constellation of Lyra It has the Bayer designation a Lyrae which is Latinised to Alpha Lyrae and abbreviated Alpha Lyr or a Lyr This star is relatively close at only 25 light years 7 7 parsecs from the Sun and one of the most luminous stars in the Sun s neighborhood It is the fifth brightest star in the night sky and the second brightest star in the northern celestial hemisphere after Arcturus VegaLocation of Vega circled Observation dataEpoch J2000 0 Equinox J2000 0Constellation LyraPronunciation ˈ v iː ɡ e 1 2 3 or ˈ v eɪ ɡ e 2 Right ascension 18h 36m 56 33635s 4 Declination 38 47 01 2802 4 Apparent magnitude V 0 026 5 0 02 0 07 6 CharacteristicsEvolutionary stage Main sequenceSpectral type A0Va 7 U B color index 0 00 8 B V color index 0 00 8 Variable type Delta Scuti 6 AstrometryRadial velocity Rv 13 9 0 9 9 km sProper motion m RA 200 94 4 mas yr Dec 286 23 4 mas yrParallax p 130 23 0 36 mas 4 Distance25 04 0 07 ly 7 68 0 02 pc Absolute magnitude MV 0 582 10 DetailsMass2 135 0 074 11 M Radius2 362 2 818 11 R Luminosity40 12 0 45 11 L Surface gravity log g 4 1 0 1 12 cgsTemperature9 602 180 13 8 152 10 060 K 11 note 1 KMetallicity Fe H 0 5 13 dexRotation16 5 h 14 Rotational velocity v sin i 20 48 0 11 11 km sAge455 13 11 MyrOther designationsWega 15 Lucida Lyrae 16 Alpha Lyrae a Lyrae 3 Lyrae BD 38 3238 GJ 721 HD 172167 HIP 91262 HR 7001 SAO 67174 LTT 15486 17 Database referencesSIMBADdataVega has been extensively studied by astronomers leading it to be termed arguably the next most important star in the sky after the Sun 18 Vega was the northern pole star around 12 000 BCE and will be so again around the year 13 727 when its declination will be 86 14 19 Vega was the first star other than the Sun to have its image and spectrum photographed 20 21 It was one of the first stars whose distance was estimated through parallax measurements Vega has functioned as the baseline for calibrating the photometric brightness scale and was one of the stars used to define the zero point for the UBV photometric system Vega is only about a tenth of the age of the Sun but since it is 2 1 times as massive its expected lifetime is also one tenth of that of the Sun both stars are at present approaching the midpoint of their main sequence lifetimes Compared with the Sun Vega has a lower abundance of elements heavier than helium 13 Vega is also a variable star that varies slightly in brightness It is rotating rapidly with a velocity of 236 km s at the equator This causes the equator to bulge outward due to centrifugal effects and as a result there is a variation of temperature across the star s photosphere that reaches a maximum at the poles From Earth Vega is observed from the direction of one of these poles 22 Based on observations of more infrared radiation than expected Vega appears to have a circumstellar disk of dust This dust is likely to be the result of collisions between objects in an orbiting debris disk which is analogous to the Kuiper belt in the Solar System 23 Stars that display an infrared excess due to dust emission are termed Vega like stars 24 In 2021 a candidate ultra hot Neptune on a 2 43 day orbit around Vega was discovered with the radial velocity method additionally another possible Saturn mass signal with a period of about 200 days 25 Contents 1 Nomenclature 2 Observation 3 Observational history 4 Physical characteristics 4 1 Rotation 4 2 Element abundance 4 3 Kinematics 5 Possible planetary system 5 1 Infrared excess 5 2 Debris disks 5 3 Possible planets 6 Etymology and cultural significance 7 Notes 8 References 9 External linksNomenclature Edit nbsp Vega is the brightest star in the constellation of Lyra a Lyrae Latinised to Alpha Lyrae is the star s Bayer designation The traditional name Vega earlier Wega 15 comes from a loose transliteration of the Arabic word waqi Arabic واقع meaning falling or landing via the phrase an nasr al waqi Arabic الن سر ال واقع the falling eagle 26 In 2016 the International Astronomical Union IAU organized a Working Group on Star Names WGSN 27 to catalog and standardize proper names for stars The WGSN s first bulletin of July 2016 28 included a table of the first two batches of names approved by the WGSN which included Vega for this star It is now so entered in the IAU Catalog of Star Names 29 Observation Edit nbsp The Summer TriangleVega can often be seen near the zenith in the mid northern latitudes during the evening in the Northern Hemisphere summer 30 From mid southern latitudes it can be seen low above the northern horizon during the Southern Hemisphere winter With a declination of 38 78 Vega can only be viewed at latitudes north of 51 S Therefore it does not rise at all anywhere in Antarctica or in the southernmost part of South America including Punta Arenas Chile 53 S At latitudes to the north of 51 N Vega remains continuously above the horizon as a circumpolar star Around July 1 Vega reaches midnight culmination when it crosses the meridian at that time 31 nbsp The path of the north celestial pole among the stars due to the precession Vega is the bright star near the bottomEach night the positions of the stars appear to change as the Earth rotates However when a star is located along the Earth s axis of rotation it will remain in the same position and thus is called a pole star The direction of the Earth s axis of rotation gradually changes over time in a process known as the precession of the equinoxes A complete precession cycle requires 25 770 years 32 during which time the pole of the Earth s rotation follows a circular path across the celestial sphere that passes near several prominent stars At present the pole star is Polaris but around 12 000 BCE the pole was pointed only five degrees away from Vega Through precession the pole will again pass near Vega around 14 000 CE 33 Vega is the brightest of the successive northern pole stars 15 In 210 000 years Vega will become the brightest star in the night sky 34 and will peak in brightness in 290 000 years with an apparent magnitude of 0 81 34 This star lies at a vertex of a widely spaced asterism called the Summer Triangle which consists of Vega plus the two first magnitude stars Altair in Aquila and Deneb in Cygnus 30 This formation is the approximate shape of a right triangle with Vega located at its right angle The Summer Triangle is recognizable in the northern skies for there are few other bright stars in its vicinity 35 Observational history Edit nbsp Astrophoto of Vega nbsp On the night of July 16 17 1850 Whipple and Bond made the first daguerreotype of a star Vega Astrophotography the photography of celestial objects began in 1840 when John William Draper took an image of the Moon using the daguerreotype process On 17 July 1850 Vega became the first star other than the Sun to be photographed when it was imaged by William Bond and John Adams Whipple at the Harvard College Observatory also with a daguerreotype 15 20 36 In August 1872 Henry Draper took a photograph of Vega s spectrum the first photograph of a star s spectrum showing absorption lines 21 Similar lines had already been identified in the spectrum of the Sun 37 In 1879 William Huggins used photographs of the spectra of Vega and similar stars to identify a set of twelve very strong lines that were common to this stellar category These were later identified as lines from the Hydrogen Balmer series 38 Since 1943 the spectrum of this star has served as one of the stable anchor points by which other stars are classified 39 The distance to Vega can be determined by measuring its parallax shift against the background stars as the Earth orbits the Sun The first person to publish a star s parallax was Friedrich G W von Struve when he announced a value of 0 125 arcsecond 0 125 for Vega 40 Friedrich Bessel was skeptical about Struve s data and when Bessel published a parallax of 0 314 for the star system 61 Cygni Struve revised his value for Vega s parallax to nearly double the original estimate This change cast further doubt on Struve s data Thus most astronomers at the time including Struve credited Bessel with the first published parallax result However Struve s initial result was actually close to the currently accepted value of 0 129 41 42 as determined by the Hipparcos astrometry satellite 4 43 44 The brightness of a star as seen from Earth is measured with a standardized logarithmic scale This apparent magnitude is a numerical value that decreases in value with increasing brightness of the star The faintest stars visible to the unaided eye are sixth magnitude while the brightest in the night sky Sirius is of magnitude 1 46 To standardize the magnitude scale astronomers chose Vega and several similar stars and averaged their brightness to represent magnitude zero at all wavelengths Thus for many years Vega was used as a baseline for the calibration of absolute photometric brightness scales 45 However this is no longer the case as the apparent magnitude zero point is now commonly defined in terms of a particular numerically specified flux This approach is more convenient for astronomers since Vega is not always available for calibration and varies in brightness 46 The UBV photometric system measures the magnitude of stars through ultraviolet blue and yellow filters producing U B and V values respectively Vega is one of six A0V stars that were used to set the initial mean values for this photometric system when it was introduced in the 1950s The mean magnitudes for these six stars were defined as U B B V 0 In effect the magnitude scale has been calibrated so that the magnitude of these stars is the same in the yellow blue and ultraviolet parts of the electromagnetic spectrum 47 Thus Vega has a relatively flat electromagnetic spectrum in the visual region wavelength range 350 850 nanometers most of which can be seen with the human eye so the flux densities are roughly equal 2 000 4 000 Jy 48 However the flux density of Vega drops rapidly in the infrared and is near 100 Jy at 5 micrometers 49 Photometric measurements of Vega during the 1930s appeared to show that the star had a low magnitude variability on the order of 0 03 magnitude around 2 8 note 2 luminosity This range of variability was near the limits of observational capability for that time and so the subject of Vega s variability has been controversial The magnitude of Vega was measured again in 1981 at the David Dunlap Observatory and showed some slight variability Thus it was suggested that Vega showed occasional low amplitude pulsations associated with a Delta Scuti variable 50 This is a category of stars that oscillate in a coherent manner resulting in periodic pulsations in the star s luminosity 51 Although Vega fits the physical profile for this type of variable other observers have found no such variation Thus the variability was thought to possibly be the result of systematic errors in measurement 52 53 However a 2007 article surveyed these and other results and concluded that A conservative analysis of the foregoing results suggests that Vega is quite likely variable in the 1 2 range with possible occasional excursions to as much as 4 from the mean 54 Also a 2011 article affirms that The long term year to year variability of Vega was confirmed 55 Vega became the first solitary main sequence star beyond the Sun known to be an X ray emitter when in 1979 it was observed from an imaging X ray telescope launched on an Aerobee 350 from the White Sands Missile Range 56 In 1983 Vega became the first star found to have a disk of dust The Infrared Astronomical Satellite IRAS discovered an excess of infrared radiation coming from the star and this was attributed to energy emitted by the orbiting dust as it was heated by the star 57 Physical characteristics EditVega s spectral class is A0V making it a blue tinged white main sequence star that is fusing hydrogen to helium in its core Since more massive stars use their fusion fuel more quickly than smaller ones Vega s main sequence lifetime is roughly one billion years a tenth of the Sun s 58 The current age of this star is about 455 million years 11 or up to about half its expected total main sequence lifespan After leaving the main sequence Vega will become a class M red giant and shed much of its mass finally becoming a white dwarf At present Vega has more than twice the mass 22 of the Sun and its bolometric luminosity is about 40 times the Sun s Because it is rotating rapidly approximately once every 16 5 hours 14 and seen nearly pole on its apparent luminosity calculated assuming it was the same brightness all over is about 57 times the Sun s 12 If Vega is variable then it may be a Delta Scuti type with a period of about 0 107 day 50 Most of the energy produced at Vega s core is generated by the carbon nitrogen oxygen cycle CNO cycle a nuclear fusion process that combines protons to form helium nuclei through intermediary nuclei of carbon nitrogen and oxygen This process becomes dominant at a temperature of about 17 million K 59 which is slightly higher than the core temperature of the Sun but is less efficient than the Sun s proton proton chain fusion reaction The CNO cycle is highly temperature sensitive which results in a convection zone about the core 60 that evenly distributes the ash from the fusion reaction within the core region The overlying atmosphere is in radiative equilibrium This is in contrast to the Sun which has a radiation zone centered on the core with an overlying convection zone 61 The energy flux from Vega has been precisely measured against standard light sources At 5 480 A the flux density is 3 650 Jy with an error margin of 2 62 The visual spectrum of Vega is dominated by absorption lines of hydrogen specifically by the hydrogen Balmer series with the electron at the n 2 principal quantum number 63 64 The lines of other elements are relatively weak with the strongest being ionized magnesium iron and chromium 65 The X ray emission from Vega is very low demonstrating that the corona for this star must be very weak or non existent 66 However as the pole of Vega is facing Earth and a polar coronal hole may be present 56 67 confirmation of a corona as the likely source of the X rays detected from Vega or the region very close to Vega may be difficult as most of any coronal X rays would not be emitted along the line of sight 67 68 Using spectropolarimetry a magnetic field has been detected on the surface of Vega by a team of astronomers at the Observatoire du Pic du Midi This is the first such detection of a magnetic field on a spectral class A star that is not an Ap chemically peculiar star The average line of sight component of this field has a strength of 0 6 0 3 gauss G 69 This is comparable to the mean magnetic field on the Sun 70 Magnetic fields of roughly 30 G have been reported for Vega compared to about 1 G for the Sun 56 In 2015 bright starspots were detected on the star s surface the first such detection for a normal A type star and these features show evidence of rotational modulation with a period of 0 68 day 71 Rotation Edit Vega has a rotation period of 12 5 hours 14 much faster than the Sun s rotational period but similar to and slightly slower than those of Jupiter and Saturn Because of that Vega is significantly oblate like those two planets When the radius of Vega was measured to high accuracy with an interferometer it resulted in an unexpectedly large estimated value of 2 73 0 01 times the radius of the Sun This is 60 larger than the radius of the star Sirius while stellar models indicated it should only be about 12 larger However this discrepancy can be explained if Vega is a rapidly rotating star that is being viewed from the direction of its pole of rotation Observations by the CHARA array in 2005 06 confirmed this deduction 12 nbsp Size comparison of Vega left to the Sun right The pole of Vega its axis of rotation is inclined no more than five degrees from the line of sight to the Earth At the high end of estimates for the rotation velocity for Vega is 236 2 3 7 km s 11 along the equator much higher than the observed i e projected rotational velocity because Vega is seen almost pole on This is 88 of the speed that would cause the star to start breaking up from centrifugal effects 11 This rapid rotation of Vega produces a pronounced equatorial bulge so the radius of the equator is 19 larger than the polar radius The estimated polar radius of this star is 2 362 0 012 solar radii while the equatorial radius is 2 818 0 013 solar radii 11 From the Earth this bulge is being viewed from the direction of its pole producing the overly large radius estimate The local surface gravity at the poles is greater than at the equator which produces a variation in effective temperature over the star the polar temperature is near 10 000 K while the equatorial temperature is about 8 152 K 11 This large temperature difference between the poles and the equator produces a strong gravity darkening effect As viewed from the poles this results in a darker lower intensity limb than would normally be expected for a spherically symmetric star The temperature gradient may also mean that Vega has a convection zone around the equator 12 72 while the remainder of the atmosphere is likely to be in almost pure radiative equilibrium 73 By the Von Zeipel theorem the local luminosity is higher at the poles As a result if Vega were viewed along the plane of its equator instead of almost pole on then its overall brightness would be lower As Vega had long been used as a standard star for calibrating telescopes the discovery that it is rapidly rotating may challenge some of the underlying assumptions that were based on it being spherically symmetric With the viewing angle and rotation rate of Vega now better known this will allow improved instrument calibrations 74 Element abundance Edit In astronomy those elements with higher atomic numbers than helium are termed metals The metallicity of Vega s photosphere is only about 32 of the abundance of heavy elements in the Sun s atmosphere note 3 Compare this for example to a threefold metallicity abundance in the similar star Sirius as compared to the Sun For comparison the Sun has an abundance of elements heavier than helium of about ZSol 0 0172 0 002 75 Thus in terms of abundances only about 0 54 of Vega consists of elements heavier than helium Nitrogen is slightly more abundant oxygen is only marginally less abundant and sulfur abundance is about 50 of solar On the other hand Vega has only 10 to 30 of the solar abundance for most other major elements with barium and scandium below 10 11 The unusually low metallicity of Vega makes it a weak Lambda Bootis star 76 77 However the reason for the existence of such chemically peculiar spectral class A0 F0 stars remains unclear One possibility is that the chemical peculiarity may be the result of diffusion or mass loss although stellar models show that this would normally only occur near the end of a star s hydrogen burning lifespan Another possibility is that the star formed from an interstellar medium of gas and dust that was unusually metal poor 78 The observed helium to hydrogen ratio in Vega is 0 030 0 005 which is about 40 lower than the Sun This may be caused by the disappearance of a helium convection zone near the surface Energy transfer is instead performed by the radiative process which may be causing an abundance anomaly through diffusion 79 Kinematics Edit The radial velocity of Vega is the component of this star s motion along the line of sight to the Earth Movement away from the Earth will cause the light from Vega to shift to a lower frequency toward the red or to a higher frequency toward the blue if the motion is toward the Earth Thus the velocity can be measured from the amount of shift of the star s spectrum Precise measurements of this blueshift give a value of 13 9 0 9 km s 9 The minus sign indicates a relative motion toward the Earth Motion transverse to the line of sight causes the position of Vega to shift with respect to the more distant background stars Careful measurement of the star s position allows this angular movement known as proper motion to be calculated Vega s proper motion is 202 03 0 63 milliarcseconds mas per year in right ascension the celestial equivalent of longitude and 287 47 0 54 mas y in declination which is equivalent to a change in latitude The net proper motion of Vega is 327 78 mas y 80 which results in angular movement of a degree every 11 000 years In the galactic coordinate system the space velocity components of Vega are U V W 16 1 0 3 6 3 0 8 7 7 0 3 km s for a net space velocity of 19 km s 81 The radial component of this velocity in the direction of the Sun is 13 9 km s while the transverse velocity is 9 9 km s Although Vega is at present only the fifth brightest star in the night sky the star is slowly brightening as proper motion causes it to approach the Sun 82 Vega will make its closest approach in an estimated 264 000 years at a perihelion distance of 13 2 ly 4 04 pc 83 Based on this star s kinematic properties it appears to belong to a stellar association called the Castor Moving Group However Vega may be much older than this group so the membership remains uncertain 11 This group contains about 16 stars including Alpha Librae Alpha Cephei Castor Fomalhaut and Vega All members of the group are moving in nearly the same direction with similar space velocities Membership in a moving group implies a common origin for these stars in an open cluster that has since become gravitationally unbound 84 The estimated age of this moving group is 200 100 million years and they have an average space velocity of 16 5 km s note 4 81 Possible planetary system EditThe Vega planetary system 25 Companion in order from star Mass Semimajor axis AU Orbital period days Eccentricity Inclination Radiusb unconfirmed 21 9 5 1 M 0 04555 0 00053 2 42977 0 00016 0 25 0 15 Debris disk 86 815 AU 6 2 nbsp A mid infrared 24 mm image of the debris disk around VegaInfrared excess Edit One of the early results from the Infrared Astronomy Satellite IRAS was the discovery of excess infrared flux coming from Vega beyond what would be expected from the star alone This excess was measured at wavelengths of 25 60 and 100 mm and came from within an angular radius of 10 arcseconds 10 centered on the star At the measured distance of Vega this corresponded to an actual radius of 80 astronomical units AU where an AU is the average radius of the Earth s orbit around the Sun It was proposed that this radiation came from a field of orbiting particles with a dimension on the order of a millimetre as anything smaller would eventually be removed from the system by radiation pressure or drawn into the star by means of Poynting Robertson drag 85 The latter is the result of radiation pressure creating an effective force that opposes the orbital motion of a dust particle causing it to spiral inward This effect is most pronounced for tiny particles that are closer to the star 86 Subsequent measurements of Vega at 193 mm showed a lower than expected flux for the hypothesized particles suggesting that they must instead be on the order of 100 mm or less To maintain this amount of dust in orbit around Vega a continual source of replenishment would be required A proposed mechanism for maintaining the dust was a disk of coalesced bodies that were in the process of collapsing to form a planet 85 Models fitted to the dust distribution around Vega indicate that it is a 120 astronomical unit radius circular disk viewed from nearly pole on In addition there is a hole in the center of the disk with a radius of no less than 80 AU 87 Following the discovery of an infrared excess around Vega other stars have been found that display a similar anomaly that is attributable to dust emission As of 2002 about 400 of these stars have been found and they have come to be termed Vega like or Vega excess stars It is believed that these may provide clues to the origin of the Solar System 24 Debris disks Edit By 2005 the Spitzer Space Telescope had produced high resolution infrared images of the dust around Vega It was shown to extend out to 43 330 AU at a wavelength of 24 mm 70 543 AU at 70 mm and 105 815 AU at 160 mm These much wider disks were found to be circular and free of clumps with dust particles ranging from 1 50 mm in size The estimated total mass of this dust is 3 10 3 times the mass of the Earth around 7 5 times more massive than the asteroid belt Production of the dust would require collisions between asteroids in a population corresponding to the Kuiper Belt around the Sun Thus the dust is more likely created by a debris disk around Vega rather than from a protoplanetary disk as was earlier thought 23 nbsp Artist s concept of a recent massive collision of dwarf planet sized objects that may have contributed to the dust ring around VegaThe inner boundary of the debris disk was estimated at 11 2 or 70 100 AU The disk of dust is produced as radiation pressure from Vega pushes debris from collisions of larger objects outward However continuous production of the amount of dust observed over the course of Vega s lifetime would require an enormous starting mass estimated as hundreds of times the mass of Jupiter Hence it is more likely to have been produced as the result of a relatively recent breakup of a moderate sized or larger comet or asteroid which then further fragmented as the result of collisions between the smaller components and other bodies This dusty disk would be relatively young on the time scale of the star s age and it will eventually be removed unless other collision events supply more dust 23 Observations first with the Palomar Testbed Interferometer by David Ciardi and Gerard van Belle in 2001 88 and then later confirmed with the CHARA array at Mt Wilson in 2006 and the Infrared Optical Telescope Array at Mt Hopkins in 2011 89 revealed evidence for an inner dust band around Vega Originating within 8 AU of the star this exozodiacal dust may be evidence of dynamical perturbations within the system 90 This may be caused by an intense bombardment of comets or meteors and may be evidence for the existence of a planetary system 91 Possible planets Edit Observations from the James Clerk Maxwell Telescope in 1997 revealed an elongated bright central region that peaked at 9 70 AU to the northeast of Vega This was hypothesized as either a perturbation of the dust disk by a planet or else an orbiting object that was surrounded by dust However images by the Keck telescope had ruled out a companion down to magnitude 16 which would correspond to a body with more than 12 times the mass of Jupiter 92 Astronomers at the Joint Astronomy Centre in Hawaii and at UCLA suggested that the image may indicate a planetary system still undergoing formation 93 Determining the nature of the planet has not been straightforward a 2002 paper hypothesizes that the clumps are caused by a roughly Jupiter mass planet on an eccentric orbit Dust would collect in orbits that have mean motion resonances with this planet where their orbital periods form integer fractions with the period of the planet producing the resulting clumpiness 94 nbsp Artist s impression of a planet around VegaIn 2003 it was hypothesized that these clumps could be caused by a roughly Neptune mass planet having migrated from 40 to 65 AU over 56 million years 95 an orbit large enough to allow the formation of smaller rocky planets closer to Vega The migration of this planet would likely require gravitational interaction with a second higher mass planet in a smaller orbit 96 Using a coronagraph on the Subaru Telescope in Hawaii in 2005 astronomers were able to further constrain the size of a planet orbiting Vega to no more than 5 10 times the mass of Jupiter 97 The issue of possible clumps in the debris disc was revisited in 2007 using newer more sensitive instrumentation on the Plateau de Bure Interferometer The observations showed that the debris ring is smooth and symmetric No evidence was found of the blobs reported earlier casting doubts on the hypothesized giant planet 98 The smooth structure has been confirmed in follow up observations by Hughes et al 2012 99 and the Herschel Space Telescope 100 Although a planet has yet to be directly observed around Vega the presence of a planetary system cannot yet be ruled out Thus there could be smaller terrestrial planets orbiting closer to the star The inclination of planetary orbits around Vega is likely to be closely aligned to the equatorial plane of this star 101 From the perspective of an observer on a hypothetical planet around Vega the Sun would appear as a faint 4 3 magnitude star in the Columba constellation note 5 In 2021 a paper analyzing 10 years of spectra of Vega detected a candidate 2 43 day signal around Vega statistically estimated to have only a 1 chance of being a false positive 25 Considering the amplitude of the signal the authors estimated a minimum mass of 21 9 5 1 Earth masses but considering the very oblique rotation of Vega itself of only 6 2 from Earth s perspective the planet may be aligned to this plane as well giving it an actual mass of 203 47 Earth masses 25 The researchers also detected a faint 196 4 1 6 1 9 day signal which could translate to a 80 21 Earth masses 740 190 at 6 2 inclination but is too faint to claim as a real signal with available data 25 Etymology and cultural significance EditSee also Summer Triangle Stars in astrology Vega and Vega in fiction The name is believed to be derived from the Arabic term Al Nesr al Waki النسر الواقع which appeared in the Al Achsasi al Mouakket star catalogue and was translated into Latin as Vultur Cadens the falling eagle vulture 102 note 6 The constellation was represented as a vulture in ancient Egypt 103 and as an eagle or vulture in ancient India 104 105 The Arabic name then appeared in the western world in the Alfonsine tables 106 which were drawn up between 1215 and 1270 by order of King Alfonso X 107 Medieval astrolabes of England and Western Europe used the names Wega and Alvaca and depicted it and Altair as birds 108 Among the northern Polynesian people Vega was known as whetu o te tau the year star For a period of history it marked the start of their new year when the ground would be prepared for planting Eventually this function became denoted by the Pleiades 109 The Assyrians named this pole star Dayan same the Judge of Heaven while in Akkadian it was Tir anna Life of Heaven In Babylonian astronomy Vega may have been one of the stars named Dilgan the Messenger of Light To the ancient Greeks the constellation Lyra was formed from the harp of Orpheus with Vega as its handle 16 For the Roman Empire the start of autumn was based upon the hour at which Vega set below the horizon 15 In Chinese 織女 Zhi Nǚ meaning Weaving Girl asterism refers to an asterism consisting of Vega e Lyrae and z1 Lyrae 110 Consequently the Chinese name for Vega is 織女一 Zhi Nǚ yi English the First Star of Weaving Girl 111 In Chinese mythology there is a love story of Qixi 七夕 in which Niulang 牛郎 Altair and his two children b Aquilae and g Aquilae are separated from their mother Zhinu 織女 lit weaver girl Vega who is on the far side of the river the Milky Way 112 However one day per year on the seventh day of the seventh month of the Chinese lunisolar calendar magpies make a bridge so that Niulang and Zhinu can be together again for a brief encounter The Japanese Tanabata festival in which Vega is known as Orihime 織姫 is also based on this legend 113 In Zoroastrianism Vega was sometimes associated with Vanant a minor divinity whose name means conqueror 114 The indigenous Boorong people of northwestern Victoria Australia named it as Neilloan 115 the flying loan 116 In the Srimad Bhagavatam Shri Krishna tells Arjuna that among the Nakshatras he is Abhijit which remark indicates the auspiciousness of this Nakshatra 117 Medieval astrologers counted Vega as one of the Behenian stars 118 and related it to chrysolite and winter savory Cornelius Agrippa listed its kabbalistic sign nbsp under Vultur cadens a literal Latin translation of the Arabic name 119 Medieval star charts also listed the alternate names Waghi Vagieh and Veka for this star 31 W H Auden s 1933 poem A Summer Night to Geoffrey Hoyland 120 famously opens with the couplet Out on the lawn I lie in bed Vega conspicuous overhead Vega became the first star to have a car named after it with the French Facel Vega line of cars from 1954 onwards and later on in America Chevrolet launched the Vega in 1971 121 Other vehicles named after Vega include the ESA s Vega launch system 122 and the Lockheed Vega aircraft 123 Notes Edit The polar temperature is around 2 000 K higher than at the equator due to the rapid rotation of Vega From Cox Arthur N ed 1999 Allen s Astrophysical Qualities 4th ed New York Springer Verlag p 382 ISBN 978 0 387 98746 0 Mbol 2 5 log L L 4 74 where Mbol is the bolometric magnitude L is the star s luminosity and L is the solar luminosity A Mbol variation of 0 03 gives Mbol2 Mbol1 0 03 2 5 log L1 L2 for L1 L2 100 03 2 5 1 028 or a 2 8 luminosity variation For a metallicity of 0 5 the proportion of metals relative to the Sun is given by 10 0 5 0 316 displaystyle 10 0 5 0 316 nbsp See Matteucci Francesca 2001 The Chemical Evolution of the Galaxy Astrophysics and Space Science Library Vol 253 Springer Science amp Business Media p 7 ISBN 978 0792365525 The space velocity components in the Galactic coordinate system are U 10 7 3 5 V 8 0 2 4 W 9 7 3 0 km s UVW is a Cartesian coordinate system so the Euclidean distance formula applies Hence the net velocity is v sp 10 7 2 8 0 2 9 7 2 16 5 km s displaystyle v text sp sqrt 10 7 2 8 0 2 9 7 2 16 5 text km s nbsp See Bruce Peter C 2015 Introductory Statistics and Analytics A Resampling Perspective John Wiley amp Sons p 20 ISBN 978 1118881330 The Sun would appear at the diametrically opposite coordinates from Vega at a 6h 36m 56 3364s d 38 47 01 291 which is in the western part of Columba The visual magnitude is given by m M v 5 5 log 10 displaystyle m M v 5 5 log 10 nbsp p 4 83 5 5 log 10 0 13023 4 256 displaystyle Rightarrow 4 83 5 5 times log 10 0 13023 4 256 nbsp original research See Hughes David W 2006 The Introduction of Absolute Magnitude 1902 1922 Journal of Astronomical History and Heritage 9 2 173 179 Bibcode 2006JAHH 9 173H That is a vulture on the ground with its wings folded Edward William Lane Arabic English Lexicon References Edit Vega Oxford English Dictionary Online ed Oxford University Press Subscription or participating institution membership required a b Vega Merriam Webster Dictionary Kunitzsch Paul Smart Tim 2006 A Dictionary of Modern star Names A Short Guide to 254 Star Names and Their Derivations 2nd rev ed Cambridge Massachusetts Sky Pub ISBN 978 1 931559 44 7 a b c d e f van Leeuwen F November 2007 Validation of the new Hipparcos reduction Astronomy and Astrophysics 474 2 653 664 arXiv 0708 1752 Bibcode 2007A amp A 474 653V doi 10 1051 0004 6361 20078357 S2CID 18759600 Bohlin R C Gilliland R L 2004 Hubble Space Telescope Absolute Spectrophotometry of Vega from the Far Ultraviolet to the Infrared The Astronomical Journal 127 6 3508 3515 Bibcode 2004AJ 127 3508B doi 10 1086 420715 a b Samus N N Durlevich O V et al 2009 VizieR Online Data Catalog General Catalogue of Variable Stars Samus 2007 2013 VizieR On line Data Catalog B GCVS Originally Published in 2009yCat 102025S 1 02025 Bibcode 2009yCat 102025S Gray R O Corbally C J Garrison R F McFadden M T Robinson P E 2003 Contributions to the Nearby Stars NStars Project Spectroscopy of Stars Earlier than M0 within 40 parsecs The Northern Sample I The Astronomical Journal 126 4 2048 arXiv astro ph 0308182 Bibcode 2003AJ 126 2048G doi 10 1086 378365 S2CID 119417105 a b Ducati J R 2002 VizieR Online Data Catalog Catalogue of Stellar Photometry in Johnson s 11 color system CDS ADC Collection of Electronic Catalogues 2237 Bibcode 2002yCat 2237 0D a b Evans D S June 20 24 1966 The Revision of the General Catalogue of Radial Velocities Proceedings from IAU Symposium no 30 Determination of Radial Velocities and Their Applications Vol 30 London England p 57 Bibcode 1967IAUS 30 57E Gatewood George 2008 Astrometric Studies of Aldebaran Arcturus Vega the Hyades and Other Regions The Astronomical Journal 136 1 452 460 Bibcode 2008AJ 136 452G doi 10 1088 0004 6256 136 1 452 a b c d e f g h i j k l m Yoon Jinmi et al January 2010 A New View of Vega s Composition Mass and Age The Astrophysical Journal 708 1 71 79 Bibcode 2010ApJ 708 71Y doi 10 1088 0004 637X 708 1 71 a b c d Aufdenberg J P et al 2006 First results from the CHARA Array VII Long Baseline Interferometric Measurements of Vega Consistent with a Pole On Rapidly Rotating Star Astrophysical Journal 645 1 664 675 arXiv astro ph 0603327 Bibcode 2006ApJ 645 664A doi 10 1086 504149 S2CID 13501650 a b c Kinman T et al 2002 The determination of Teff for metal poor A type stars using V and 2MASS J H and K magnitudes Astronomy and Astrophysics 391 3 1039 1052 Bibcode 2002A amp A 391 1039K doi 10 1051 0004 6361 20020806 a b c Petit P Bohm T Folsom C P Lignieres F Cang T 2022 A decade long magnetic monitoring of Vega Astronomy and Astrophysics 666 A20 arXiv 2208 09196 Bibcode 2022A amp A 666A 20P doi 10 1051 0004 6361 202143000 S2CID 251710497 a b c d e Allen Richard Hinckley 1963 Star Names Their Lore and Meaning Courier Dover Publications ISBN 978 0 486 21079 7 a b Kendall E Otis 1845 Uranography Or A Description of the Heavens Designed for Academics and Schools Accompanied by an Atlas of the Heavens Philadelphia Oxford University Press Staff V alf Lyr Variable Star SIMBAD Retrieved October 30 2007 use the display all measurements option to show additional parameters Gulliver Austin F et al 1994 Vega A rapidly rotating pole on star The Astrophysical Journal 429 2 L81 L84 Bibcode 1994ApJ 429L 81G doi 10 1086 187418 Calculation by the Stellarium application version 0 10 2 Retrieved July 28 2009 a b Barger M Susan et al 2000 First published 1991 The Daguerreotype Nineteenth Century Technology and Modern Science JHU Press p 88 ISBN 978 0 8018 6458 2 a b Barker George F 1887 On the Henry Draper Memorial Photographs of Stellar Spectra Proceedings of the American Philosophical Society 24 166 172 a b Peterson D M et al 2006 Vega is a rapidly rotating star Nature 440 7086 896 899 arXiv astro ph 0603520 Bibcode 2006Natur 440 896P doi 10 1038 nature04661 PMID 16612375 S2CID 533664 a b c Su K Y L et al 2005 The Vega Debris Disk A Surprise from Spitzer The Astrophysical Journal 628 1 487 500 arXiv astro ph 0504086 Bibcode 2005ApJ 628 487S doi 10 1086 430819 S2CID 18898968 a b Song Inseok et al 2002 M Type Vega like Stars The Astronomical Journal 124 1 514 518 arXiv astro ph 0204255 Bibcode 2002AJ 124 514S doi 10 1086 341164 S2CID 3450920 a b c d e Hurt Spencer A Quinn Samuel N Latham David W Vanderburg Andrew Esquerdo Gilbert A Calkins Michael L Berlind Perry Angus Ruth Latham Christian A Zhou George January 21 2021 A Decade of Radial velocity Monitoring of Vega and New Limits on the Presence of Planets The Astronomical Journal 161 4 157 arXiv 2101 08801 Bibcode 2021AJ 161 157H doi 10 3847 1538 3881 abdec8 S2CID 231693198 Glasse Cyril 2008 The new encyclopedia of Islam Reference Information and Interdisciplinary Subjects Series 3rd ed Rowman amp Littlefield p 75 ISBN 978 0 7425 6296 7 IAU Working Group on Star Names WGSN International Astronomical Union Retrieved May 22 2016 Bulletin of the IAU Working Group on Star Names No 1 PDF IAU Division C Education Outreach and Heritage WGSN July 2016 Retrieved July 28 2016 IAU Catalog of Star Names IAU Division C Education Outreach and Heritage WGSN August 21 2016 Retrieved July 28 2016 a b Pasachoff Jay M 2000 A Field Guide to Stars and Planets 4th ed Houghton Mifflin Field Guides ISBN 978 0 395 93431 9 a b Burnham Robert J R 1978 Burnham s Celestial Handbook An Observer s Guide to the Universe Beyond the Solar System Vol 2 Courier Dover Publications ISBN 978 0 486 23568 4 Chaikin Andrew L 1990 Beatty J K Petersen C C eds The New Solar System 4th ed Cambridge England Cambridge University Press ISBN 978 0 521 64587 4 Roy Archie E et al 2003 Astronomy Principles and Practice CRC Press ISBN 978 0 7503 0917 2 a b Tomkin Jocelyn April 1998 Once and Future Celestial Kings Sky and Telescope 95 4 59 63 Bibcode 1998S amp T 95d 59T based on computations from HIPPARCOS data The calculations exclude stars whose distance or proper motion is uncertain PDF permanent dead link Upgren Arthur R 1998 Night Has a Thousand Eyes A Naked Eye Guide to the Sky Its Science and Lore Basic Books Bibcode 1998nhte book U ISBN 978 0 306 45790 6 Holden Edward S et al 1890 Photographs of Venus Mercury and Alpha Lyrae in Daylight Publications of the Astronomical Society of the Pacific 2 10 249 250 Bibcode 1890PASP 2 249H doi 10 1086 120156 S2CID 120286863 Spectroscopy and the Birth of Astrophysics Tools of Cosmology American Institute of Physics Retrieved March 29 2022 Hentschel Klaus 2002 Mapping the Spectrum Techniques of Visual Representation in Research and Teaching Oxford University Press ISBN 978 0 19 850953 0 Garrison R F December 1993 Anchor Points for the MK System of Spectral Classification Bulletin of the American Astronomical Society 25 1319 Bibcode 1993AAS 183 1710G Archived from the original on June 25 2019 Retrieved February 5 2012 Berry Arthur 1899 A Short History of Astronomy New York Charles Scribner s Sons ISBN 978 0 486 20210 5 Dick Wolfgang R Ruben G 1988 The First Successful Attempts to Determine Stellar Parallaxes in the Light of the Bessel Struve Correspondence Mapping the Sky Past Heritage and Future Directions Springer pp 119 121 doi 10 1017 S007418090013949X ISBN 978 90 277 2810 4 Anonymous June 28 2007 The First Parallax Measurements Astroprof Retrieved November 12 2007 Perryman M A C et al 1997 The Hipparcos Catalogue Astronomy and Astrophysics 323 L49 L52 Bibcode 1997A amp A 323L 49P Perryman Michael 2010 The Making of History s Greatest Star Map Astronomers Universe Heidelberg Springer Verlag Bibcode 2010mhgs book P doi 10 1007 978 3 642 11602 5 ISBN 978 3 642 11601 8 Garfinkle Robert A 1997 Star Hopping Your Visa to Viewing the Universe Cambridge University Press ISBN 978 0 521 59889 7 Cochran A L 1981 Spectrophotometry with a self scanned silicon photodiode array II Secondary standard stars Astrophysical Journal Supplement Series 45 83 96 Bibcode 1981ApJS 45 83C doi 10 1086 190708 Johnson H L et al 1953 Fundamental stellar photometry for standards of spectral type on the revised system of the Yerkes spectral atlas Astrophysical Journal 117 313 352 Bibcode 1953ApJ 117 313J doi 10 1086 145697 Walsh J March 6 2002 Alpha Lyrae HR7001 Optical and UV Spectrophotometric Standard Stars ESO Archived from the original on February 9 2007 Retrieved November 15 2007 flux versus wavelength for Vega McMahon Richard G November 23 2005 Notes on Vega and magnitudes Text University of Cambridge Retrieved November 7 2007 a b Fernie J D 1981 On the variability of Vega Publications of the Astronomical Society of the Pacific 93 2 333 337 Bibcode 1981PASP 93 333F doi 10 1086 130834 Gautschy A et al 1995 Stellar Pulsations Across The HR Diagram Part 1 Annual Review of Astronomy and Astrophysics 33 1 75 114 Bibcode 1995ARA amp A 33 75G doi 10 1146 annurev aa 33 090195 000451 I A Vasil yev et al March 17 1989 On the Variability of Vega Commission 27 of the I A U Retrieved October 30 2007 Hayes D S May 24 29 1984 Stellar absolute fluxes and energy distributions from 0 32 to 4 0 microns Proceedings of the Symposium Calibration of fundamental stellar quantities Calibration of Fundamental Stellar Quantities Vol 111 pp 225 252 Bibcode 1985IAUS 111 225H Gray Raymond 2007 The Problems with Vega The Future of Photometric Spectrophotometric and Polarimetric Standardization ASP Conference Series Proceedings of a Conference Held 8 11 May 2006 in Blankenberge Belgium 364 305 Bibcode 2007ASPC 364 305G Butkovskaya Varvara 2011 The long term variability of Vega Astronomische Nachrichten 332 9 10 956 960 Bibcode 2011AN 332 956B doi 10 1002 asna 201111587 a b c Topka K et al 1979 Detection of soft X rays from Alpha Lyrae and Eta Bootis with an imaging X ray telescope Astrophysical Journal 229 661 Bibcode 1979ApJ 229 661T doi 10 1086 157000 Harvey Paul E et al 1984 On the far infrared excess of Vega Nature 307 5950 441 442 Bibcode 1984Natur 307 441H doi 10 1038 307441a0 S2CID 4330793 Mengel J G et al 1979 Stellar evolution from the zero age main sequence Astrophysical Journal Supplement Series 40 733 791 Bibcode 1979ApJS 40 733M doi 10 1086 190603 From pages 769 778 for stars in the range 1 75 lt M lt 2 2 0 2 lt Y lt 0 3 and 0 004 lt Z lt 0 01 stellar models give an age range of 0 43 1 64 109 years between a star joining the main sequence and turning off to the red giant branch With a mass closer to 2 2 however the interpolated age for Vega is less than a billion Salaris Maurizio et al 2005 Evolution of Stars and Stellar Populations John Wiley and Sons p 120 ISBN 978 0 470 09220 0 Browning Matthew et al 2004 Simulations of core convection in rotating A type stars Differential rotation and overshooting Astrophysical Journal 601 1 512 529 arXiv astro ph 0310003 Bibcode 2004ApJ 601 512B doi 10 1086 380198 S2CID 16201995 Padmanabhan Thanu 2002 Theoretical Astrophysics Cambridge University Press ISBN 978 0 521 56241 6 Oke J B et al 1970 The Absolute Spectral Energy Distribution of Alpha Lyrae Astrophysical Journal 161 1015 1023 Bibcode 1970ApJ 161 1015O doi 10 1086 150603 Richmond Michael The Boltzmann Equation Rochester Institute of Technology Retrieved November 15 2007 Clayton Donald D 1983 Principles of Stellar Evolution and Nucleosynthesis University of Chicago Press ISBN 978 0 226 10953 4 Michelson E 1981 The near ultraviolet stellar spectra of alpha Lyrae and beta Orionis Monthly Notices of the Royal Astronomical Society 197 57 74 Bibcode 1981MNRAS 197 57M doi 10 1093 mnras 197 1 57 Schmitt J H M M 1999 Coronae on solar like stars Astronomy and Astrophysics 318 215 230 Bibcode 1997A amp A 318 215S a b Vaiana G S 1980 A K Dupree ed Stellar Coronae Overview of the Einstein CFA Stellar Survey In Cool Stars Stellar Systems and the Sun SAO Special Report 389 389 195 215 Bibcode 1980SAOSR 389 195V Munro R H et al May 1977 Physical properties of a polar coronal hole from 2 to 5 solar radii Astrophysical Journal 213 5 874 86 Bibcode 1977ApJ 213 874M doi 10 1086 155220 Lignieres F et al 2009 First evidence of a magnetic field on Vega Astronomy amp Astrophysics 500 3 L41 L44 arXiv 0903 1247 Bibcode 2009A amp A 500L 41L doi 10 1051 0004 6361 200911996 S2CID 6021105 Staff July 26 2009 Magnetic Field On Bright Star Vega Science Daily Retrieved July 30 2009 Bohm T et al May 2015 Discovery of starspots on Vega First spectroscopic detection of surface structures on a normal A type star Astronomy amp Astrophysics 577 12 arXiv 1411 7789 Bibcode 2015A amp A 577A 64B doi 10 1051 0004 6361 201425425 S2CID 53548120 A64 Staff January 10 2006 Rapidly Spinning Star Vega has Cool Dark Equator National Optical Astronomy Observatory Retrieved November 18 2007 Adelman Saul J July 2004 The physical properties of normal A stars Proceedings of the International Astronomical Union 2004 IAUS224 1 11 Bibcode 2004IAUS 224 1A doi 10 1017 S1743921304004314 Quirrenbach Andreas 2007 Seeing the Surfaces of Stars Science 317 5836 325 326 doi 10 1126 science 1145599 PMID 17641185 S2CID 118213499 Antia H M et al 2006 Determining Solar Abundances Using Helioseismology The Astrophysical Journal 644 2 1292 1298 arXiv astro ph 0603001 Bibcode 2006ApJ 644 1292A doi 10 1086 503707 S2CID 15334093 Renson P et al 1990 Catalogue of Lambda Bootis Candidates Bulletin d Information du Centre de Donnees Stellaires 38 137 149 Bibcode 1990BICDS 38 137R Entry for HD 172167 on p 144 Qiu H M et al 2001 The Abundance Patterns of Sirius and Vega The Astrophysical Journal 548 2 77 115 Bibcode 2001ApJ 548 953Q doi 10 1086 319000 Martinez Peter et al 1998 The pulsating lambda Bootis star HD 105759 Monthly Notices of the Royal Astronomical Society 301 4 1099 1103 Bibcode 1998MNRAS 301 1099M doi 10 1046 j 1365 8711 1998 02070 x Adelman Saul J et al 1990 An elemental abundance analysis of the superficially normal A star Vega Astrophysical Journal Part 1 348 712 717 Bibcode 1990ApJ 348 712A doi 10 1086 168279 Majewski Steven R 2006 Stellar Motions University of Virginia Archived from the original on January 25 2012 Retrieved September 27 2007 The net proper motion is given by m m d 2 m a 2 cos 2 d 327 78 mas y displaystyle begin smallmatrix mu sqrt mu delta 2 mu alpha 2 cdot cos 2 delta 327 78 text mas y end smallmatrix nbsp where m a displaystyle mu alpha nbsp and m d displaystyle mu delta nbsp are the components of proper motion in the R A and Declination respectively and d displaystyle delta nbsp is the Declination a b Barrado y Navascues D 1998 The Castor moving group The age of Fomalhaut and VEGA Astronomy and Astrophysics 339 831 839 arXiv astro ph 9905243 Bibcode 1998A amp A 339 831B Moulton Forest Ray 1906 An Introduction to Astronomy The Macmillan company p 502 Bailer Jones C A L March 2015 Close encounters of the stellar kind Astronomy amp Astrophysics 575 13 arXiv 1412 3648 Bibcode 2015A amp A 575A 35B doi 10 1051 0004 6361 201425221 S2CID 59039482 A35 Inglis Mike 2003 Observer s Guide to Stellar Evolution The Birth Life and Death of Stars Springer ISBN 978 1 85233 465 9 a b Harper D A et al 1984 On the nature of the material surrounding VEGA Astrophysical Journal Part 1 285 808 812 Bibcode 1984ApJ 285 808H doi 10 1086 162559 Robertson H P April 1937 Dynamical effects of radiation in the solar system Monthly Notices of the Royal Astronomical Society 97 6 423 438 Bibcode 1937MNRAS 97 423R doi 10 1093 mnras 97 6 423 Dent W R F et al 2000 Models of the dust structures around Vega excess stars Monthly Notices of the Royal Astronomical Society 314 4 702 712 Bibcode 2000MNRAS 314 702D doi 10 1046 j 1365 8711 2000 03331 x Ciardi David R et al 2001 On The Near Infrared Size of Vega The Astrophysical Journal 559 1 237 244 arXiv astro ph 0105561 Bibcode 2001ApJ 559 1147C doi 10 1086 322345 S2CID 15898697 Defrere D et al 2011 Hot exozodiacal dust resolved around Vega with IOTA IONIC Astronomy and Astrophysics 534 A5 arXiv 1108 3698 Bibcode 2011A amp A 534A 5D doi 10 1051 0004 6361 201117017 S2CID 8291382 Absil O et al 2006 Circumstellar material in the Vega inner system revealed by CHARA FLUOR Astronomy and Astrophysics 452 1 237 244 arXiv astro ph 0604260 Bibcode 2006A amp A 452 237A doi 10 1051 0004 6361 20054522 S2CID 2165054 Girault Rime Marion Summer 2006 Vega s Stardust CNRS International Magazine Retrieved November 19 2007 Holland Wayne S et al 1998 Submillimetre images of dusty debris around nearby stars Nature 392 6678 788 791 Bibcode 1998Natur 392 788H doi 10 1038 33874 S2CID 4373502 Staff April 21 1998 Astronomers discover possible new Solar Systems in formation around the nearby stars Vega and Fomalhaut Joint Astronomy Centre Archived from the original on December 16 2008 Retrieved October 29 2007 Wilner D et al 2002 Structure in the Dusty Debris around Vega The Astrophysical Journal 569 2 L115 L119 arXiv astro ph 0203264 Bibcode 2002ApJ 569L 115W doi 10 1086 340691 S2CID 36818074 Wyatt M 2003 Resonant Trapping of Planetesimals by Planet Migration Debris Disk Clumps and Vega s Similarity to the Solar System The Astrophysical Journal 598 2 1321 1340 arXiv astro ph 0308253 Bibcode 2003ApJ 598 1321W doi 10 1086 379064 S2CID 10755059 Gilchrist E et al December 1 2003 New evidence for Solar like planetary system around nearby star Royal Observatory Edinburgh Retrieved October 30 2007 Itoh Yoichi et al 2006 Coronagraphic Search for Extrasolar Planets around e Eri and Vega The Astrophysical Journal 652 2 1729 1733 arXiv astro ph 0608362 Bibcode 2006ApJ 652 1729I doi 10 1086 508420 S2CID 119542260 Pietu V et al July 2011 High sensitivity search for clumps in the Vega Kuiper belt New PdBI 1 3 mm observations Astronomy amp Astrophysics 531 L2 arXiv 1105 2586 Bibcode 2011A amp A 531L 2P doi 10 1051 0004 6361 201116796 S2CID 55674804 Hughes A Meredith et al 2012 Confirming the Primarily Smooth Structure of the Vega Debris Disk at Millimeter Wavelengths The Astrophysical Journal 750 1 82 arXiv 1203 0318 Bibcode 2012ApJ 750 82H doi 10 1088 0004 637X 750 1 82 S2CID 118553890 82 Sibthorpe B et al 2010 The Vega debris disc A view from Herschel Astronomy and Astrophysics 518 L130 arXiv 1005 3543 Bibcode 2010A amp A 518L 130S doi 10 1051 0004 6361 201014574 S2CID 6461181 L130 Campbell B et al 1985 On the inclination of extra solar planetary orbits Publications of the Astronomical Society of the Pacific 97 180 182 Bibcode 1985PASP 97 180C doi 10 1086 131516 Knobel E B June 1895 Al Achsasi Al Mouakket on a catalogue of stars in the Calendarium of Mohammad Al Achsasi Al Mouakket Monthly Notices of the Royal Astronomical Society 55 8 429 438 Bibcode 1895MNRAS 55 429K doi 10 1093 mnras 55 8 429 Massey Gerald 2001 Ancient Egypt the Light of the World Adamant Media Corporation ISBN 978 1 60206 086 9 Olcott William Tyler 1911 Star Lore of All Ages A Collection of Myths Legends and Facts Concerning the Constellations of the Northern Hemisphere G P Putnam s sons Bibcode 1911slaa book O ISBN 978 0 7873 1096 7 Houlding Deborah December 2005 Lyra The Lyre Sktscript Retrieved November 4 2007 Kunitzsch Paul 1986 The Star Catalogue Commonly Appended to the Alfonsine Tables Journal for the History of Astronomy 17 49 89 98 Bibcode 1986JHA 17 89K doi 10 1177 002182868601700202 S2CID 118597258 Houtsma M Th et al 1987 E J Brill s First Encyclopaedia of Islam 1913 36 Vol VII E J Brill p 292 Gingerich O 1987 Zoomorphic Astrolabes and the Introduction of Arabic Star Names into Europe Annals of the New York Academy of Sciences 500 1 89 104 Bibcode 1987NYASA 500 89G doi 10 1111 j 1749 6632 1987 tb37197 x S2CID 84102853 Smith S Percy 1919 The Fatherland of the Polynesians Aryan and Polynesian Points of Contact The Journal of the Polynesian Society 28 18 20 陳久金 2005 中國星座神話 五南圖書出版股份有限公司 ISBN 978 986 7332 25 7 天文教育資訊網 AEEA Activities of Exhibition and Education in Astronomy in Chinese July 3 2006 Retrieved January 6 2019 Wei Liming et al 2005 Chinese Festivals Chinese Intercontinental Press ISBN 978 7 5085 0836 8 Kippax John Robert 1919 The Call of the Stars A Popular Introduction to a Knowledge of the Starry Skies with their Romance and Legend G P Putnam s Sons Boyce Mary 1996 A History of Zoroastrianism volume one The Early Period New York E J Brill ISBN 978 90 04 08847 4 Hamacher Duane W et al 2010 An Aboriginal Australian Record of the Great Eruption of Eta Carinae Journal of Astronomical History amp Heritage 13 3 220 34 arXiv 1010 4610 Bibcode 2010JAHH 13 220H doi 10 3724 SP J 1440 2807 2010 03 06 S2CID 118454721 Stanbridge William Edward 1857 On the astronomy and mythology of the Aborigines of Victoria Proceedings of the Philosophical Institute of Victoria 2 137 Bibcode 1857PPIVT 2 137S SB 11 16 27 vedabase io Retrieved March 29 2021 Tyson Donald et al 1993 Three Books of Occult Philosophy Llewellyn Worldwide ISBN 978 0 87542 832 1 Agrippa Heinrich Cornelius 1533 De Occulta Philosophia ISBN 978 90 04 09421 5 W H Auden A Summer Night to Geoffrey Hoyland Retrieved January 6 2019 Frommert Hartmut Vega Alpha Lyrae SEDS Archived from the original on October 24 2007 Retrieved November 2 2007 Staff May 20 2005 Launch vehicles Vega European Space Agency Retrieved November 12 2007 Rumerman Judy 2003 The Lockheed Vega and Its Pilots U S Centennial of Flight Commission Archived from the original on October 18 2007 Retrieved November 12 2007 External links Edit nbsp Wikimedia Commons has media related to Vega Anonymous Vega SolStation The Sol Company Retrieved November 9 2005 Gilchrist Eleanor et al December 1 2003 New evidence for Solar like planetary system around nearby star Joint Astronomy Centre Archived from the original on September 23 2009 Retrieved November 10 2007 Hill Gay Yee et al January 10 2005 Spitzer Sees Dusty Aftermath of Pluto Sized Collision NASA Spitzer Space Telescope Archived from the original on May 18 2007 Retrieved November 2 2007 Portals nbsp Astronomy nbsp Stars nbsp Outer space Retrieved from https en wikipedia org w index php title Vega amp oldid 1180968606, wikipedia, wiki, book, books, library,

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