Twilight is the illumination of the Earth's lower atmosphere when the Sun itself is not directly visible because it is below the horizon. Twilight is produced by sunlight scattering in the upper atmosphere, illuminating the lower atmosphere so that the surface of the Earth is neither completely lit nor completely dark. The word twilight is also used to denote the periods of time when this illumination occurs.
The further the Sun is below the horizon, the dimmer the twilight (other things such as atmospheric conditions being equal). When the Sun reaches 18 degrees below the horizon, the twilight's brightness is nearly zero, and evening twilight becomes nighttime. When the Sun again reaches 18 degrees below the horizon, nighttime becomes morning twilight. Owing to its distinctive quality, primarily the absence of shadows and the appearance of objects silhouetted against the bright sky, twilight has long been popular with photographers, who refer to it as 'sweet light', and painters, who refer to it as the blue hour, after the French expression: l'heure bleue.
Twilight should not be confused with auroras, which can have a similar appearance in the night sky at high latitudes.
By analogy with evening twilight, the word twilight is also sometimes used metaphorically, to imply that something is losing strength and approaching its end. For example, very old people may be said to be "in the twilight of their lives". The collateral adjective for twilight is crepuscular; it is most frequently encountered when applied to certain insects, fish and mammals that are most active during that time.
- 1 Definitions
- 2 Times of occurrence
- 3 Duration
- 4 On other planets
- 5 In religion
- 6 Gallery
- 7 See also
- 8 References
- 9 Footnotes
- 10 Further reading
- 11 External links
Twilight is defined according to the solar elevation angle θs, which is the position of the geometric center of the sun relative to the horizon. There are three established and widely accepted subcategories of twilight: civil twilight (brightest), nautical twilight, and astronomical twilight (darkest).
Morning civil twilight begins when the geometric center of the sun is 6° below the horizon (civil dawn), and ends at sunrise  or when the geometric center of the sun is 0°50′ below the horizon. Evening civil twilight begins at sunset  or when the geometric center of the sun is 0°50′ below the horizon, and ends when the geometric center of the sun reaches 6° below the horizon (civil dusk). In the United States' military, the initialisms BMCT (begin morning civil twilight, i.e. civil dawn) and EECT (end evening civil twilight, i.e. civil dusk) are used to refer to these periods.
Civil twilight is approximately the limit at which solar illumination is sufficient, under clear weather conditions, for terrestrial objects to be clearly distinguished. There is enough light from the sun during this period that artificial sources of light are not needed to carry on most outdoor activities.
At the beginning of morning civil twilight, or end of evening civil twilight, the horizon is clearly defined and the brightest stars are visible under clear atmospheric conditions. The brightest planets can appear during this time. Venus, the brightest planet as observed from the Earth (see apparent magnitude), is known as the "morning star" or "evening star" due to its visibility during civil twilight.
This concept is sometimes enshrined in laws, for example, when drivers of automobiles must turn on their headlights (called lighting-up time in the UK); when pilots require a night rating to fly aircraft; restrictions on hunting; or if the crime of burglary is to be treated as nighttime burglary, which carries stiffer penalties in some jurisdictions. Such statutes typically use a fixed period after sunset or before sunrise (most commonly 20–30 minutes), rather than how many degrees the sun is below the horizon.
Morning nautical twilight is defined to begin when the geometric center of the sun is 12° below the horizon. According to some definitions, it ends when the geometric center of the sun is 0°50′ below the horizon. There are other definitions that state that morning nautical twilight ends when the geometric center of the sun is 6° below the horizon. According to some definitions, evening nautical twilight begins when the geometric center of the sun is 0°50′ below the horizon. There are other definitions that state that evening nautical twilight begins when the geometric center of the sun is 6° below the horizon. Evening nautical twilight is defined to end when the geometric center of the sun is 12° below the horizon. In general, nautical twilight ends when navigation via the horizon at sea is no longer possible.
During nautical twilight, sailors can take reliable star sightings of well-known stars, using a visible horizon for reference. The end of this period in the evening, or its beginning in the morning, is also the time at which traces of illumination near the sunset or sunrise point of the horizon are very difficult, if not impossible, to discern (this often being referred to as "first light" before civil dawn and "nightfall" after civil dusk). At the beginning of nautical twilight in the morning (nautical dawn), or at the end of nautical twilight in the evening (nautical dusk), and under good atmospheric conditions with the absence of other illumination, general outlines of ground objects may be distinguishable; but detailed outdoor operations are not possible, and the horizon is indistinct.
Nautical twilight has military considerations as well. The initialisms BMNT (begin morning nautical twilight, i.e. nautical dawn) and EENT (end evening nautical twilight, i.e. nautical dusk) are used and considered when planning military operations. A military unit may treat BMNT and EENT with heightened security, e.g. by "standing to", in which everyone assumes a defensive position. This is partially due to tactics dating back to the French and Indian War (part of the Seven Years' War of 1756–1763), when combatants on both sides would launch attacks at nautical dawn or dusk.
Morning astronomical twilight is defined to begin when the geometric center of the Sun is 18° below the horizon. According to some definitions, it ends when the geometric center of the sun is 0°50′ below the horizon. There are other definitions that state that it begins when the geometric center of the sun is 12° below the horizon. Evening astronomical twilight is defined to end when the geometric center of the sun is 18° below the horizon. From the end of astronomical twilight in the evening to the beginning of astronomical twilight in the morning, the sky (away from urban light pollution, moonlight, auroras, and other sources of light in the sky) is dark enough for nearly all astronomical observations. In some places, especially those with sky glow, astronomical twilight may be almost indistinguishable from night.
Most casual observers would consider the entire sky fully dark even when astronomical twilight is just beginning in the evening or just ending in the morning, and astronomers can easily make observations of point sources such as stars. However, some critical observations, such as of faint diffuse items such as nebulae and galaxies, may require that the sun be more than 18° below the horizon, beyond the limit of astronomical twilight.
Theoretically, the dimmest stars ever visible to the naked eye (those of the sixth magnitude) will become visible in the evening once the sun falls more than 18° below the horizon (i.e., at astronomical dusk), and become invisible when the sun moves to within 18° of the horizon in the morning (at astronomical dawn). However, because of light pollution, some localities, generally those in large cities, may never have the opportunity to view even fourth-magnitude stars, irrespective of the presence of any twilight at all, and to experience truly dark skies.
Times of occurrence
Twilight between day and night
The most familiar occurrences of twilight are between dawn and sunrise and between sunset and dusk each day. These occur for observers at latitudes within 48.5 degrees of the Equator on all dates of the year, and also for most observers at higher latitudes on many dates. However, at latitudes closer than 9 degrees to either Pole, the Sun cannot rise above the horizon and go more than 18 degrees below it on the same day on any date, so this type of twilight cannot occur as the angular elevation difference between solar noon and solar midnight is less than 18 degrees.
Twilight lasting from one day to the next
At latitudes greater than about 48.5 degrees North or South, on dates near the summer solstice, twilight can last from sunset to sunrise, since the Sun does not go more than 18 degrees below the horizon, so complete darkness does not occur even at midnight. These latitudes include many densely populated regions of the Earth, including the entire United Kingdom and other countries in northern Europe.
Twilight between one night and the next
In Arctic and Antarctic latitudes in wintertime, the polar night only rarely produces complete darkness for 24 hours each day. This can occur only at locations within 5.5 degrees of latitude of the Pole, and there only on dates close to the winter solstice. At all other latitudes and dates, the polar night includes a daily period of twilight, when the Sun is not far below the horizon. Around winter solstice, when the solar declination changes slowly, complete darkness lasts several weeks at the pole itself, e.g., from May 14 to July 28 at Amundsen–Scott South Pole Station.[a]
Twilight lasting for 24 hours
At latitudes within 9 degrees of either pole, as the sun's angular elevation difference is less than 18 degrees, twilight can last for the entire 24 hours. This occurs for one day at latitudes near 9 degrees from the pole and extends up to several weeks the further towards the pole one goes. The only permanent settlement to experience this condition is Alert, Nunavut, Canada, where it occurs for a week in late February, and again in late October.
The apparent travel of the sun occurs at the rate of 15 degrees per hour (360° per day), but sunrise and sunset happen typically at oblique angles to the horizon and the actual duration of any twilight period will be a function of that angle, being longer for more oblique angles. This angle of the sun's motion with respect to the horizon changes with latitude as well as the time of year (affecting the angle of the Earth's axis with respect to the sun).
At Greenwich, England (51.5°N), the duration of civil twilight will vary from 33 minutes to 48 minutes, depending on the time of year. At the equator, conditions can go from day to night in as little as 20–25 minutes. This is true because at low latitudes the sun's apparent movement is perpendicular to the observer's horizon. But at the poles, civil twilight can be as long as 2–3 weeks. In the Arctic and Antarctic regions, twilight (if there is any) can last for several hours. There is no astronomical twilight at the poles near the winter solstice (for about 74 days at the North Pole and about 80 days at the South Pole). As one gets closer to the Arctic and Antarctic circles, the sun's disk moves toward the observer's horizon at a lower angle. The observer's earthly location will pass through the various twilight zones less directly, taking more time.
Within the polar circles, twenty-four-hour daylight is encountered in summer, and in regions very close to the poles, twilight can last for weeks on the winter side of the equinoxes. Outside the polar circles, where the angular distance from the polar circle is less than the angle which defines twilight (see above), twilight can continue through local midnight near the summer solstice. The precise position of the polar circles, and the regions where twilight can continue through local midnight, varies slightly from year to year with Earth's axial tilt. The lowest latitudes at which the various twilights can continue through local midnight are approximately 60.561° (60°33′43″) for civil twilight, 54.561° (54°33′43″) for nautical twilight and 48.561° (48°33′43″) for astronomical twilight.
These are the largest cities of their respective countries where the various twilights can continue through local solar midnight:
- Civil twilight from sunset to sunrise: Tampere, Umeå, Trondheim, Tórshavn, Reykjavík, Nuuk, Whitehorse, Anchorage, and Baltasound.
- Nautical twilight from civil dusk to civil dawn: Moscow, Vitebsk, Vilnius, Riga, Tallinn, Wejherowo, Flensburg, Helsinki, Stockholm, Copenhagen, Oslo, Newcastle upon Tyne, Glasgow, Belfast, Letterkenny, Petropavl, Grande Prairie, Juneau, Ushuaia, and Puerto Williams.
- Astronomical twilight from nautical dusk to nautical dawn: Hulun Buir, Erdenet, Astana, Samara, Kiev, Minsk, Warsaw, Košice, Paris, Dublin, Zwettl, Prague, Stanley (Falkland Islands), Berlin, Luxembourg City, Brussels, Amsterdam, London, Cardiff, Calgary, Unalaska (Bellingham, largest in the continental USA), Rio Gallegos, and Punta Arenas.
- Major cities that near astronomical twilight from nautical dusk to nautical dawn: Saguenay (48°25′0"N), Brest (48°23′26"N), Thunder Bay (48°22′56″N), Vienna (48°12′30″N), Bratislava (48°8′38″N), Munich (48°8'0″N)
Although Helsinki, Oslo, Stockholm, Tallinn, and Saint Petersburg also enter into nautical twilight after sunset, they do have noticeably lighter skies at night (known as white nights) around the summer solstice than other locations mentioned in their category above, because they do not go far into nautical twilight.
At the winter solstice within the polar circle, twilight can extend through solar noon at latitudes below 72.561° (72°33′43″) for civil twilight, 78.561° (78°33′43″) for nautical twilight, and 84.561° (84°33′43″) for astronomical twilight.
On other planets
Twilight on Mars is longer than on Earth, lasting for up to two hours before sunrise or after sunset. Dust high in the atmosphere scatters light to the night side of the planet. Similar twilights are seen on Earth following major volcanic eruptions.
In Christian practice, "vigil" observances often occur during twilight on the evening before major feast days or holidays. For example, the Easter Vigil is held in the hours of darkness between sunset on Holy Saturday and sunrise on Easter Day — most commonly in the evening of Holy Saturday or midnight — and is the first celebration of Easter, days traditionally being considered to begin at sunset.
Twilight is sacred in Hinduism. It is called गोधूळिवेळ gōdhūḷivēḷ in Marathi or गोधूलिवेला godhūlivelā in Hindi, గొధూళివేళ "godhoolivela" in Telugu, literally "cow dust time". Many rituals, including Sandhyavandanam and Puja, are performed at twilight hour. Eating of food is not advised during this time. Sometimes it is referred to as Asurasandhya vela. It is believed that Asuras are active during these hours. One of the avatars of Lord Vishnu, Narasimha, is closely associated with the twilight period. According to Hindu scriptures, a daemonic king, Hiranyakashipa, performed penance and obtained a boon from Brahma not to be killed during days or night times and neither by human nor animal. As Godhulivela is not regarded as either day or night, Lord Vishnu ended the life of Hiranakashipa during these hours.
Twilight is important in Islam as it determines when certain universally obligatory prayers are to be recited. Morning twilight is when morning prayers (Fajr) are done, while evening twilight is the time for evening prayers (Maghrib prayer). Suhoor (early morning meal) time for fasting (during Ramadan and other times) ends at morning twilight (at dawn). Fasting is from the beginning of dawn to sunset. There is also an important discussion in Islamic jurisprudence between "true dawn" and "false dawn".
In Judaism, twilight is considered neither day nor night; consequently it is treated as a safeguard against encroachment upon either. For example, the twilight of Friday is reckoned as Sabbath eve, and that of Saturday as Sabbath day; and the same rule applies to festival days.
View from the Chiang Kai-shek Memorial Hall, Taipei, Taiwan.
Twilight before Sunrise, Landers, California.
Clouds begin to glow with colors at nautical dawn, the second stage of twilight, when the Sun is 12 degrees below the horizon.
- "Definitions from the US Astronomical Applications Dept (USNO)". Retrieved 2011-07-22.
- Van Flandern, T.; K. Pulkkinen (1980). "Low precision formulae for planetary positions". Astrophysical Journal Supplement Series 31 (3). Bibcode:1979ApJS...41..391V. doi:10.1086/190623.
- ftp://ftp.flaterco.com/xtide/Bowditch.pdf#238 The American Practical Navigator, 2002; page 238
- http://msi.nga.mil/MSISiteContent/StaticFiles/NAV_PUBS/APN/Gloss-1.pdf#9 Glossary of Marine Navigation
- http://www.ast.cam.ac.uk/public/ask/2445 University of Cambridge - Institute of Astronomy - Ask an Astronomer
- "Venus and the Moon strike a pose". Retrieved 18 April 2016.
- "Length of Day and Twilight (Formulas)". www.gandraxa.com. Retrieved 2011-08-26.
- Herbert Glarner's website, reference 2. "Civil Twilight" "6°", "Nautical Twilight" "12°". "90°-Axis(23.439°)-12°=54.561°.
- NASA-Jet Propulsion Laboratory: Winter Solstice on Mars: Rovers Look Forward to A Second Martian Spring, August 07, 2006.
- Jossleyn Hennessy (1955). "ch. VII Education in the villages "Cow-dust time"". India democracy and education. Orient Longmans. p. 127.
- "A strong showing at Paranal". Retrieved 6 July 2015.
- This is the range of dates when the Sun is more than 18 degrees north of the Celestial equator, so it is more than 18 degrees below the horizon as seen from the South Pole. See Position of the Sun#Declination of the Sun as seen from Earth.
- Mateshvili, Nina; Didier Fussen; Filip Vanhellemont; Christine Bingen; Erkki Kyrölä; Iuri Mateshvili; Giuli Mateshvili (2005). "Twilight sky brightness measurements as a useful tool for stratospheric aerosol investigations". Journal of Geophysical Research 110 (D09209): D09209. Bibcode:2005JGRD..11009209M. doi:10.1029/2004JD005512.
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|Wikimedia Commons has media related to Twilight.|
- Twilight Calculator Compute twilight times.
- Definition of Twilight US Naval Observatory.
- Twilight time calculator
- Formulae to calculate twilight duration by Herbert Glarner.
- The colors of twilight and sunset
- HM Nautical Almanac Office Websurf Compute twilight times.
- Geoscience Australia "Sunrise and sunset times" Compute twilight times.
- "Twilight". Collier's New Encyclopedia. 1921.
- "Twilight". The New Student's Reference Work. 1914.
- An Excel workbook with VBA functions for twilight (dawn and dusk), sunrise, solar noon, sunset, and solar position (azimuth and elevation) by Greg Pelletier, translated from NOAA's online calculator for sunrise/sunset