For other uses, see Light year (disambiguation).
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A light-year, also light year or lightyear (symbol: ly) is a unit of length, equal to just under 10 trillion kilometres (10×1015 metres, 10 petametres or about 6 trillion miles). As defined by the International Astronomical Union (IAU), a light-year is the distance that light travels in avacuum in one Julian year.[1]
The light-year is often used to measure distances to stars and other distances on a galactic scale, especially in non-specialist and popular science publications. The preferred unit in astrometry is the parsec, because it can be more easily derived from, and compared with, observational data. The parsec is defined as the distance at which an object will appear to move one arcsecond of parallax when the observer moves one astronomical unit perpendicular to the line of sight to the observer, and is equal to approximately 3.26 light-years.[1]
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[edit]Numerical value
| SI units | |
|---|---|
| 9.461×1012 km | 9.461×1015 m |
| Astronomical units | |
| 63.24×103 AU | 0.3066 pc |
| US customary / Imperial units | |
| 5.879×1012 mi | 31.04×1015 ft |
One light-year is equal to:
- exactly 9,460,730,472,580.8 km (about 9.5 Pm)
- about 5,878,625,373,183.6 miles (about 6 trillion miles)
- about 63,241.1 astronomical units
- about 0.306601 parsecs
- exactly 31,557,600 light-seconds
The figures above are based on a Julian year (not Gregorian year) of exactly 365.25 days (each of exactly 86,400 SI seconds, totalling 31,557,600 seconds)[2] and a defined speed of light of 299,792,458 m/s, both included in the IAU (1976) System of Astronomical Constants, used since 1984.[3]
[edit]Other values
Before 1984, the tropical year (not the Julian year) and a measured (not defined) speed of light were included in the IAU (1964) System of Astronomical Constants, used from 1968 to 1983.[4] The product of Simon Newcomb's J1900.0 mean tropical year of 31,556,925.9747 ephemeris seconds and a speed of light of 299,792.5 km/s produced a light-year of9.460530×1015 m (rounded to the seven significant digits in the speed of light) found in several modern sources[5][6][7] was probably derived from an old source such as a reputable 1973 reference[8] which was not updated until 2000.[9]
Other high-precision values are not derived from a coherent IAU system. A value of 9.460536207×1015 m found in some modern sources[10][11] is the product of a mean Gregorian year of 365.2425 days (31,556,952 s) and the defined speed of light (299,792,458 m/s). Another value, 9.460528405×1015 m,[12][13] is the product of the J1900.0 mean tropical year and the defined speed of light.
[edit]History
The first successful measurement of the distance to a star other than our Sun was made by Friedrich Bessel in 1838. The star was 61 Cygni, and he used a superlative 6.2-inch (160 mm) heliometer designed by Joseph von Fraunhofer. The largest unit for measuring distances across space at that time was the Astronomical Unit (AU), equal to the radius of the Earth's orbit (1.50×108 km; 9.30×107 mi). The use of this unit in trigonometric calculations based on 61 Cygni's parallax of 0.314 arcseconds, gave the distance to the star as 660,000 AU (9.9×1013 km; 6.1×1013 mi). Bessel realised that a much larger unit of measurement was needed to make the vast interstellar distances comprehensible.
James Bradley had stated in 1729 that light travelled 10,210 times faster than the Earth in its orbit. In 1769, a transit of Venus revealed the distance of the Earth from the Sun, and this, together with Bradley's figure, allowed the speed of light to be calculated as 3.01×108 m/s, very close to the modern value.
Bessel used this speed to work out how far light would travel in a year, and announced that the distance to 61 Cygni was 10.3 light-years. This was the first appearance of the light-year as a measurement of distance, and, although modern astronomers prefer the parsec, it is popularly used to gauge the expanses of interstellar and intergalactic space.
[edit]Distances in light-years
Distances measured in fractions of a light-year (or in light-months) usually involve objects within a star system. Distances measured in light-years include distances between nearbystars, such as those in the same spiral arm or globular cluster.
One kilolight-year, abbreviated "kly", is one thousand light-years (about 307 parsecs). Kilolight-years are typically used to measure distances between parts of a galaxy.
One megalight-year, abbreviated "Mly", is one million light-years (about 307 kiloparsecs). Megalight-years are typically used to measure distances between neighbouring galaxies andgalaxy clusters.
One gigalight-year, abbreviation "Gly", is one billion (109) light-years—one of the largest distance measures used. Gigalight-years are typically used to measure distances to supergalactic structures, including quasars and the Great Wall.
| Scale (ly) | Value | Item |
|---|---|---|
| 10−9 | 40.4×10−9ly | Reflected sunlight from the Moon's surface takes 1.2–1.3 seconds to travel the distance to the Earth's surface. (The surface of the Moon is roughly 376,300 kilometres from the surface of the Earth, on average. 376,300 km ÷ 300,000 km/s (roughly the speed of light) ≈ 1.25 seconds) |
| 10−6 | 15.8×10−6ly | One astronomical unit (the distance from the Sun to the Earth). It takes approximately 499 seconds (8.32 minutes) for light to travel this distance.[14] |
| 127×10−6ly | The Huygens probe lands on Titan and transmits images from its surface 1200 million kilometres to the Earth. | |
| 10−3 | 3.2×10−3ly | The most distant space probe, Voyager 1, was about 16 light-hours away from the Earth as of 2011. It will take about 17,500 years to reach one light-year at its current speed of about 17 km/s (38,000 mph) relative to the Sun.[15] |
| 100 | 1.6×100 ly | The Oort cloud is approximately two light-years in diameter. Its inner boundary is speculated to be at 50,000 AU, with its outer edge at 100,000 AU. |
| 2.0×100 ly | Maximum extent of the Sun's gravitational dominance (hill sphere/roche sphere, 125,000 AU). Beyond this is the true interstellar medium. | |
| 4.22×100ly | The nearest known star (other than the Sun), Proxima Centauri, is about 4.22 light-years away.[16][17] | |
| 8.60×100ly | Sirius, the brightest star of the night sky. Twice as massive and 25 times more luminous than the Sun, it outshines more luminous stars due to its relative proximity. | |
| 20.5×100ly | Gliese 581g, the first discovered extrasolar candidate for habitable planet. Three or four times as massive as the Earth, it is in the middle of the habitable zone of star Gliese 581. | |
| 310×100ly | Canopus, second in brightness in the terrestrial sky only to Sirius, a type F supergiant 15,000 times more luminous than the Sun. | |
| 103 | 26×103 ly | The centre of our galaxy, the Milky Way, is about 26 kilolight-years away.[18][19] |
| 100×103ly | The Milky Way is about 100,000 light-years across. | |
| 165×103ly | R136a1, in the Large Magellanic Cloud, the most luminous star known at 8,700,000 times the luminosity of the Sun, has an apparent magnitude 12.77, just brighter than 3C 273 | |
| 106 | 2.5×106 ly | The Andromeda Galaxy is approximately 2.5 megalight-years away. |
| 3×106 ly | The Triangulum Galaxy (M33), at about 3 megalight-years away, is the most distant object visible to the naked eye. | |
| 59×106 ly | The nearest large galaxy cluster, the Virgo Cluster, is about 59 megalight-years away. | |
| 150×106 – 250×106ly | The Great Attractor lies at a distance of somewhere between 150 and 250 megalight-years (the latter being the most recent estimate). | |
| 109 | 1.2×109 ly | The Sloan Great Wall (not to be confused with the Great Wall) has been measured to be approximately one gigalight-year distant. |
| 2.4×109 ly | 3C 273, optically the brightest quasar, of apparent magnitude 12.9, just dimmer than R136a1. | |
| 46.5×109ly | The comoving distance from the Earth to the edge of the visible universe is about 46.5 gigalight-years in any direction; this is the comoving radius of the observable universe. This is larger than the age of the universe dictated by the cosmic background radiation; see size of the universe: misconceptions for why this is possible. |
[edit]Light-month
The related unit of the light-month, roughly one-twelfth of a light-year, is also used occasionally for approximate measures.[20][21] The Hayden Planetarium specifies the light month more precisely as 30 days of light travel time.[22]
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