Astronomy:Terminator (solar)

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Short description: Line dividing day and night on a celestial body
Earth's terminator as seen from space

A terminator or twilight zone is a moving line that divides the daylit side and the dark night side of a planetary body. The terminator is defined as the locus of points on a planet or moon where the line through the center of its parent star is tangent. An observer on the terminator of such an orbiting body with an atmosphere would experience twilight due to light scattering by particles in the gaseous layer.

Earth's terminator

On Earth, the terminator is a circle with a diameter that is approximately that of Earth.[1] The terminator passes through any point on Earth's surface twice a day, at sunrise and at sunset, apart from polar regions where this only occurs when the point is not experiencing midnight sun or polar night. The circle separates the portion of Earth experiencing daylight from that experiencing darkness (night). While a little over one half of Earth is illuminated at any point in time (with exceptions during eclipses), the terminator path varies by time of day due to Earth's rotation on its axis. The terminator path also varies by time of year due to Earth's orbital revolution around the Sun; thus, the plane of the terminator is nearly parallel to planes created by lines of longitude during the equinoxes, and its maximum angle is approximately 23.5° to the pole during the solstices.[2]

Surface transit speed

File:ISS flies over Africa, the Mideast, and the Terminator line.ogv At the equator, under flat conditions (without obstructions like mountains or at a height above any such obstructions), the terminator moves at approximately 463 metres per second (1,040 mph). This speed can appear to increase when near obstructions, such as the height of a mountain, as the shadow of the obstruction will be cast over the ground in advance of the terminator along a flat landscape. The speed of the terminator decreases as it approaches the poles, where it can reach a speed of zero (full-day sunlight or darkness).[3]

Supersonic aircraft like jet fighters or Concorde and Tupolev Tu-144 supersonic transports are the only aircraft able to overtake the maximum speed of the terminator at the equator. However, slower vehicles can overtake the terminator at higher latitudes, and it is possible to walk faster than the terminator at the poles, near to the equinoxes. The visual effect is that of seeing the sun rise in the west, or set in the east.

Grey-line radio propagation

Strength of radio propagation changes between day- and night-side of the ionosphere. This is primarily because the D layer, which absorbs high frequency signals, disappears rapidly on the dark side of the terminator, whereas the E and F layers above the D layer take longer to form.[4] This time-difference puts the ionosphere into a unique intermediate state along the terminator, called the "grey line".[5]

Amateur radio operators take advantage of conditions along the terminator to perform long-distance communications. Called "gray-line" or "grey-line" propagation, this signal path is a type of skywave propagation. Under good conditions, radio waves can travel along the terminator to antipodal points.[5]

Gallery

Lunar terminator

An oblique view of the large lunar crater Keeler at the terminator (from Apollo 13)
The east side of Timocharis crater while at the terminator (from Apollo 15)
Mosaic of Apollo 16 photos along the terminator showing Darney, Lubiniezky, and Bullialdus craters

The lunar terminator is the division between the illuminated and dark hemispheres of the Moon.[6] It is the lunar equivalent of the division between night and day on the Earth spheroid, although the Moon's much lower rate of rotation[7] means it takes longer for it to pass across the surface. At the equator, it moves at 15.4 kilometres per hour (9.6 mph), as fast as an athletic human can run on earth.

Due to the angle at which sunlight strikes this portion of the Moon, shadows cast by craters and other geological features are elongated, thereby making such features more apparent to the observer. This phenomenon is similar to the lengthening of shadows on Earth when the Sun is low in the sky. For this reason, much lunar photographic study centers on the illuminated area near the lunar terminator, and the resulting shadows provide accurate descriptions of the lunar terrain.

Lunar terminator illusion

The lunar terminator (or tilt) illusion is an optical illusion arising from the expectation of an observer on Earth that the direction of sunlight illuminating the Moon (i.e. a line perpendicular to the terminator) should correspond with the position of the Sun, but does not appear to do so. The illusion results from misinterpreting the arrangement of objects in the sky according to intuition based on planar geometry.[8][9]

Scientific significance

Examination of a terminator can yield information about the surface of a planetary body; for example, the presence of an atmosphere can create a fuzzier terminator. As the particles within an atmosphere are at a higher elevation, the light source can remain visible even after it has set at ground level. These particles scatter the light, reflecting some of it to the ground. Hence, the sky can remain illuminated even after the sun has set. Images showing a planetary terminator can be used to map topography: the position of the tip of a mountain behind the terminator line is measured when the Sun still or already illuminates it while the base of the mountain remains in shadow.[10] 

Low Earth orbit satellites take advantage of the fact that certain polar orbits set near the terminator do not suffer from eclipse, therefore their solar cells are continuously lit by sunlight. Such orbits are called dawn-dusk orbits, a type of Sun-synchronous orbit. This prolongs the operational life of a LEO satellite, as onboard battery life is prolonged. It also enables specific experiments that require minimum interference from the Sun, as the designers can opt to install the relevant sensors on the dark side of the satellite.

See also

References

  1. Mackenzie, Fred T.; Lerman, Abraham (2006-12-29) (in en). Carbon in the Geobiosphere: – Earth's Outer Shell –. Springer Science & Business Media. ISBN 9781402042386. https://books.google.com/books?id=TiGgJip0l64C&q=earth%27s+terminator+is+circle+size+of+earth&pg=PA67. 
  2. "SOS:Day Night Terminator". http://sos.noaa.gov/datasets/Land/day_night.html. 
  3. Venus Revealed by David Harry Grinspoon, page 329
  4. Adrian Weiss. (2011). Ionospheric Propagation, Transmission Lines, and Antennas for the QRP DXer, pp. 1–16, 1-22–1-24. Green Valley, AZ: Milliwatt QRP Books.
  5. 5.0 5.1 "Propagation". http://dx.qsl.net/propagation/. 
  6. "List of basic lunar features". http://brahms.phy.vanderbilt.edu/a103/labs/tl_moon.shtml. 
  7. The lunar day cycle is 29.53 Earth days in length (see [1]), so the terminator moves across the lunar surface at 15.4 kilometers per hour.
  8. Jones, Christopher B. (January 2014). "Lunar Terminator Illusion". http://chrisjones.id.au/MoonIllusion/. 
  9. Myers-Beaghton, Andrea K.; Myers, Alan L.. "The Moon Tilt Illusion". http://www.seas.upenn.edu/~amyers/MoonPaper20June.pdf. 
  10. Furger, Markus (February 2009). "Cloud-base or mountain shadow?". Weather 64 (2): 53. doi:10.1002/wea.352. ISSN 0043-1656. Bibcode2009Wthr...64...53F. 

External links