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More conveniently, atmospheric refraction is ignored and the center of the sun is often used in place of the upper limb for computing a day's duration. When [[sunrise]] and [[sunset]] do occur, the day duration can be computed as 2ω<sub>o</sub>/15°, where ω<sub>o</sub> is the [[sunset]] [[hour angle]] in degrees (°) given by the [[sunrise equation|sunset equation]]. When [[sunrise]] and [[sunset]] do not occur during the course of a day, the day duration is either 0 or 24 hours.
More conveniently, atmospheric refraction is ignored and the center of the sun is often used in place of the upper limb for computing a day's duration. When [[sunrise]] and [[sunset]] do occur, the day duration can be computed as 2ω<sub>o</sub>/15°, where ω<sub>o</sub> is the [[sunset]] [[hour angle]] in degrees (°) given by the [[sunrise equation|sunset equation]]. When [[sunrise]] and [[sunset]] do not occur during the course of a day, the day duration is either 0 or 24 hours.


==Historical variation of day length==
==Increasing day length==


The earth is constantly losing angular momentum and rotational energy through a process called [[tidal acceleration]], which leads to a slow lengthening of the day. A century ago, the average day was about 1.7 [[millisecond]]s shorter than today,<ref>[[Dennis McCarthy (scientist)|McCarthy, D.D.]] & Seidelmann, P.K. ''TIME: From Earth Rotation to Atomic Physics.'' Weinheim: Wiley-VCH. (2009). pp. 88&ndash;89</ref> while in the late [[Neoproterozoic]] about 620 million years ago a day had only about 21.9±0.4 hours.<ref>{{Cite journal | doi = 10.1029/1999RG900016 | last1 = Williams | first1 = George E. | year = 2000 | title = Geological constraints on the Precambrian history of Earth's rotation and the Moon's orbit | bibcode = 2000RvGeo..38...37W | journal = Reviews of Geophysics | volume = 38 | issue = 1| pages = 37–60 }}</ref>
The earth is constantly losing angular momentum and rotational energy through a process called [[tidal acceleration]], which leads to a slow lengthening of the day. A century ago, the average day was about 1.7 [[millisecond]]s shorter than today,<ref>[[Dennis McCarthy (scientist)|McCarthy, D.D.]] & Seidelmann, P.K. ''TIME: From Earth Rotation to Atomic Physics.'' Weinheim: Wiley-VCH. (2009). pp. 88&ndash;89</ref> while in the late [[Neoproterozoic]] about 620 million years ago a day had only about 21.9±0.4 hours.<ref>{{Cite journal | doi = 10.1029/1999RG900016 | last1 = Williams | first1 = George E. | year = 2000 | title = Geological constraints on the Precambrian history of Earth's rotation and the Moon's orbit | bibcode = 2000RvGeo..38...37W | journal = Reviews of Geophysics | volume = 38 | issue = 1| pages = 37–60 }}</ref>

Revision as of 15:21, 10 October 2013

This redirect is about duration of sunlight in a day. For the rotation of the Earth around its own axis, see Earth's rotation § Rotation_period. For the length of a mean solar day compared to a uniform time scale, see ΔT.
Day length as a function of latitude and the day of the year

Day length, or length of day, or length of daytime, is the time each day from the moment the upper limb of the sun's disk appears above the horizon during sunrise to the moment when the upper limb disappears below the horizon during sunset. Because of the diffusion and refraction of sunlight by the atmosphere, there is actually daylight even when the sun is slightly below the horizon. The period when it is still somewhat light even though the sun is below the horizon is called twilight.

Description

In general, the length of a day varies throughout the year, and depends upon latitude. This variation is caused by the tilt of the Earth's axis of rotation with respect to the ecliptic plane of the Earth around the sun. At the solstice occurring about June 20–22, the north pole is tilted toward the sun, and therefore the northern hemisphere has days ranging in duration from just over 12 hours in the southern portion of the Tropic of Cancer to 24 hours in the Arctic Circle, while the southern hemisphere has days ranging in duration from just under 12 hours in the northern portion of the Tropic of Capricorn to zero in the Antarctic Circle. At the equinox occurring about September 22–23, the poles are neither tilted toward nor away from the sun, and the duration of a day is generally about 12 hours all over the Earth. At the solstice occurring about December 20–22, the south pole is tilted toward the sun, and therefore the southern hemisphere has days ranging in duration from just over 12 hours in the northern portion of the Tropic of Capricorn to 24 hours in the Antarctic Circle, whereas the northern hemisphere has days ranging in duration from just under 12 hours in the southern portion of the Tropic of Cancer to zero in the Arctic Circle. At the equinox occurring about March 19–21, the poles are again aligned so that the duration of a day is generally about 12 hours all over the Earth.

In each hemisphere, the higher the latitude, the shorter the day during winter. Between winter and summer solstice, the day's duration increases, and the rate of increase is larger the higher the latitude. A fast increase of day length is what allows a very short day on winter solstice at 60 degrees latitude (either north or south) to reach about 12 hours by the spring equinox, while a slower increase is required for a much longer day on winter solstice at 20 degrees latitude (again, either north or south) to reach 12 hours by the spring equinox. The rate of change of day duration is generally fastest at the equinoxes, although at high latitudes the change is similar for several weeks before and after the equinoxes. The rate of change of day duration at each solstice is zero as the change goes from positive to negative, or vice versa.

Some interesting facts are as follows:

  • On the Equator, the duration of daylight is not exactly 12 hours all the year round, but rather — because of atmospheric refraction and the size of the Sun — exceeds 12 hours by about 7 minutes each day;
  • Because the sun is north of the equator for almost 4 days more than half the year, because of the eccentricity of Earth's orbit, the duration of the average day at a given latitude in the northern hemisphere exceeds the duration of the average day at the same latitude in the southern hemisphere by a few minutes;
  • During a few days around the equinoxes—about March 19–22 and September 21–24—both poles experience simultaneously 24 hours of daytime, mainly because of atmospheric refraction.
  • Each pole has only one sunrise and one sunset per year, around the time of the equinoxes. Each pole’s sunrise is nearly coincident with the other's sunset, with minor differences mainly resulting from atmospheric refraction.

Alternate definition

Day length, sunset and sunrise in Madrid (40º25') during 2011.
Sunshine at 12:00 UTC during a year

More conveniently, atmospheric refraction is ignored and the center of the sun is often used in place of the upper limb for computing a day's duration. When sunrise and sunset do occur, the day duration can be computed as 2ωo/15°, where ωo is the sunset hour angle in degrees (°) given by the sunset equation. When sunrise and sunset do not occur during the course of a day, the day duration is either 0 or 24 hours.

Increasing day length

The earth is constantly losing angular momentum and rotational energy through a process called tidal acceleration, which leads to a slow lengthening of the day. A century ago, the average day was about 1.7 milliseconds shorter than today,[1] while in the late Neoproterozoic about 620 million years ago a day had only about 21.9±0.4 hours.[2]

See also

References

  1. ^ McCarthy, D.D. & Seidelmann, P.K. TIME: From Earth Rotation to Atomic Physics. Weinheim: Wiley-VCH. (2009). pp. 88–89
  2. ^ Williams, George E. (2000). "Geological constraints on the Precambrian history of Earth's rotation and the Moon's orbit". Reviews of Geophysics. 38 (1): 37–60. Bibcode:2000RvGeo..38...37W. doi:10.1029/1999RG900016.
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