ART

The zodiacal light (also called false dawn[1][2][3] when seen before sunrise) is a faint, diffuse, and roughly triangular white glow that is visible in the night sky and appears to extend from the Sun's direction and along the zodiac, straddling the ecliptic.[4] Sunlight scattered by interplanetary dust causes this phenomenon. Zodiacal light is best seen during twilight after sunset in spring and before sunrise in autumn, when the zodiac is at a steep angle to the horizon. However, the glow is so faint that moonlight and/or light pollution outshine it, rendering it invisible.

The brightness of zodiacal light decreases with distance from the Sun. In naturally dark night skies, the glow is visible as a band along the entire zodiac, completely straddling the ecliptic. In fact, zodiacal light spans the entire sky and largely[5] contributes to the total natural light in a clear and moonless night sky. Another phenomenon – a faint but slightly brighter oval glow – directly opposite of the Sun is the gegenschein, which is caused by backscattered sunlight.

The interplanetary dust in the Solar System collectively forms a thick, pancake-shaped cloud called the zodiacal cloud, which straddles the ecliptic plane. The particle sizes range between 10 and 300 micrometres, implying masses from one nanogram to tens of micrograms.[6][7]

The Pioneer 10 spacecraft observations in the 1970s linked zodiacal light with the interplanetary dust cloud in the Solar System.[8]

Viewing
Zodiacal light seen behind the Submillimeter Array from the summit of Mauna Kea

In the mid-latitudes, the zodiacal light is best observed in the western sky in the spring after the evening twilight has completely disappeared, or in the eastern sky in the autumn just before the morning twilight appears. The zodiacal light appears as a column, brighter at the horizon, tilted at the angle of the ecliptic. The light scattered from extremely small dust particles is strongly forward scattering, although the zodiacal light actually extends all the way around the sky, hence it is brightest when observing at a small angle with the Sun. This is why it is most clearly visible near sunrise or sunset when the sun is blocked, but the dust particles nearest the line of sight to the sun are not. The dust band that causes the zodiacal light is uniform across the whole ecliptic.

The dust further from the ecliptic is almost undetectable except when viewed at a small angle with the sun. Thus it is possible to see more of the width at small angles toward the sun, and it appears wider near the horizon, closer to the sun under the horizon.
Origin
Moonlight and zodiacal light over La Silla Observatory.[9]

The source of the dust has been long debated. Until recently, it was thought that the dust originated from the tails of active comets and from collisions between asteroids in the asteroid belt.[10] Many of our meteor showers have no known active comet parent bodies. Over 85 percent of the dust is attributed to occasional fragmentations of Jupiter-family comets that are nearly dormant.[11] Jupiter-family comets have orbital periods of less than 20 years[12] and are considered dormant when not actively outgassing, but may do so in the future.[13] The first fully dynamical model of the zodiacal cloud demonstrated that only if the dust was released in orbits that approach Jupiter, is it stirred up enough to explain the thickness of the zodiacal dust cloud. The dust in meteoroid streams is much larger, 300 to 10,000 micrometres in diameter, and falls apart into smaller zodiacal dust grains over time.
Colorful center of the Milky Way and the zodiacal light above the Very Large Telescope.[14]

The Poynting–Robertson effect forces the dust into more circular (but still elongated) orbits, while spiralling slowly into the Sun. Hence a continuous source of new particles is needed to maintain the zodiacal cloud. Cometary dust and dust generated by collisions among the asteroids are believed to be mostly responsible for the maintenance of the dust cloud producing the zodiacal light and the gegenschein.

Particles can be reduced in size by collisions or by space weathering. When ground down to sizes less than 10 micrometres, the grains are removed from the inner Solar System by solar radiation pressure. The dust is then replenished by the infall from comets. Zodiacal dust around nearby stars is called exozodiacal dust; it is a potentially important source of noise for directly imaging extrasolar planets. It has been pointed out that this exozodiacal dust, or hot debris disks, can be an indicator of planets, as planets tend to scatter the comets to the inner Solar System.

In 2015, new results from the secondary ion dust spectrometer COSIMA on board the ESA/Rosetta orbiter confirmed that the parent bodies of interplanetary dust are most probably Jupiter-family comets such as comet 67P/Churyumov-Gerasimenko.[15] Data from the Juno mission indicate that the dust close to Earth has a local origin in the inner Solar System, best fitting the planet Mars as a source.[16]
Appearance
False dawn[17]
Zodiacal light seen from Cerro Paranal

Zodiacal light is produced by sunlight reflecting off dust particles in the Solar System known as cosmic dust. Consequently, its spectrum is the same as the solar spectrum. The material producing the zodiacal light is located in a lens-shaped volume of space centered on the sun and extending well out beyond the orbit of Earth. This material is known as the interplanetary dust cloud. Since most of the material is located near the plane of the Solar System, the zodiacal light is seen along the ecliptic. The amount of material needed to produce the observed zodiacal light is quite small. If it were in the form of 1 mm particles, each with the same albedo (reflecting power) as Earth's moon, each particle would be 8 km from its neighbors. The gegenschein may be caused by particles directly opposite the Sun as seen from Earth, which would be in full phase.

According to Nesvorný and Jenniskens, when the dust grains are as small as about 150 micrometres in size, they will hit the Earth at an average speed of 14.5 km/s, many as slowly as 12 km/s. If so, they pointed out, this comet dust can survive entry in partially molten form, accounting for the unusual attributes of the micrometeorites collected in Antarctica, which do not resemble the larger meteorites known to originate from asteroids. In recent years, observations by a variety of spacecraft have shown significant structure in the zodiacal light including dust bands associated with debris from particular asteroid families and several cometary trails.
Cultural significance

According to Alexander von Humboldt's Kosmos, Mesoamericans were aware of the zodiacal light before 1500.[18] It was perhaps first reported in print by Joshua Childrey in 1661. The phenomenon was investigated by the astronomer Giovanni Domenico Cassini in 1683. According to some sources, he explained it by dust particles around the Sun.[19][20] Other sources state that it was first explained this way by Nicolas Fatio de Duillier, in 1684,[21] whom Cassini advised to study the zodiacal light.[18]
Importance to Islam

The Islamic prophet Muhammad described zodiacal light in reference to the timing of the five daily prayers, calling it the "false dawn" (الفجر الكاذب al-fajr al-kādhib). Muslim oral tradition preserves numerous sayings, or hadith, in which Muhammad describes the difference between the light of false dawn, appearing in the sky long after sunset, and the light of the first band of horizontal light at sunrise, the "true dawn" (الفجر الصادق al-fajr al-sādiq).[22][23] According to the vast majority of Muslim scholars, astronomical dawn is considered the true dawn. Practitioners of Islam use Muhammad's descriptions of zodiacal light to avoid errors in determining the timing of daily prayers. Such practical descriptions and applications of astronomical observations were vital to the golden age of Islamic astronomy.

Use of the term "false dawn" in this context should not be confused with false sunrise, which is a different, unrelated optical phenomenon.
See also

Astronomy portal

Exozodiacal dust
Interplanetary dust cloud
Optical phenomenon
Kordylewski cloud

References

"APOD: 2012 January 16 - Zodiacal Light and the False Dawn".
"What are Zodiacal Lights?".
http://earthsky.org/astronomy-essentials/everything-you-need-to-know-zodiacal-light-or-false-dawn
Darling, David. "Zodiacal cloud". Internet Encyclopedia of Science.
Reach, W. T. (1997). "The structured zodiacal light: IRAS, COBE, and ISO observations". Diffuse Infrared Radiation and the Irts. 124: 1. Bibcode:1997ASPC..124...33R.
Peucker-Ehrenbrink, Bernhard; Schmitz, Birger (2001). Accretion of extraterrestrial matter throughout earth's history. Springer. pp. 66–67. ISBN 978-0-306-46689-2.
McCracken, C. W. (1967). "Conditions of encounter between dust and the planets". Smithsonian Contributions to Astrophysics. 11: 213. Bibcode:1967SCoA...11..213M.
Hanner, M. S. (1976). "Pioneer 10 observations of zodiacal light brightness near the ecliptic: Changes with heliocentric distance". Interplanetary Dust and Zodiacal Light. Lecture Notes in Physics. 48: 29–35. Bibcode:1976LNP....48...29H. doi:10.1007/3-540-07615-8_448. ISBN 978-3-540-07615-5.
"Moonlight and Zodiacal Light Over La Silla". ESO Picture of the Week. Retrieved 21 July 2013.
Espy, Ashley J.; Dermott, S.; Kehoe, T. J. (September 2006). "Towards a Global Model of the Zodiacal Cloud". Bulletin of the American Astronomical Society. 38: 557. Bibcode:2006DPS....38.4101E.
Nesvorný, David; Jenniskens, Peter; Levison, Harold F.; Bottke, William F.; Vokrouhlický, David; Gounelle, Matthieu (April 20, 2010). "Cometary Origin of the Zodiacal Cloud and Carbonaceous Micrometeorites. Implications for hot debris disks". Astrophysical Journal. 713 (2): 816–836. arXiv:0909.4322. Bibcode:2010ApJ...713..816N. doi:10.1088/0004-637x/713/2/816. S2CID 18865066.
Jenniskens, Petrus Matheus Marie (2006). Meteor showers and their parent comets. Cambridge University Press. p. 108. ISBN 978-0-521-85349-1.
SPACE.com Staff (6 January 2011). "Comet or Asteroid? Big Space Rock Has Identity Crisis". SPACE.com. Retrieved 23 May 2011. "Dormant comets retain some subsurface volatiles and may start outgassing once again as they near the sun."
"Romantic Sunset over the VLT". www.eso.org. European Southern Observatory. Retrieved 21 April 2015.
Rita Schulz; et al. (12 February 2015). "Comet 67P/Churyumov-Gerasimenko sheds dust coat accumulated over the past four years". Nature. 518 (7538): 216–218. Bibcode:2015Natur.518..216S. doi:10.1038/nature14159. PMID 25624103. S2CID 205242328.
Space Daily: Juno data shatter ideas about origin of Zodiacal Light
"False Dawn". www.eso.org. Retrieved 14 February 2017.
Ley, Willy (April 1961). "The Puzzle Called Gegenschein". For Your Information. Galaxy Science Fiction. pp. 74–84.
Petrus Matheus Marie Jenniskens (14 September 2006). Meteor Showers and Their Parent Comets. Cambridge University Press. p. 531. ISBN 978-0-521-85349-1.
Bernard Grun (9 August 2001). Interplanetary Dust. Springer. p. 58. ISBN 978-3-540-42067-5.
Steven J. Dick (31 August 2013). Discovery and Classification in Astronomy: Controversy and Consensus. Cambridge University Press. p. 350. ISBN 978-1-107-03361-0.
https://sunnah.com/muslim/13/52

"Sahih Moslim (The Authentic Hadiths of Muslim) 1-4 Vol 2: صحيح مسلم 1/4 [عربي/إنكليزي] ج2". January 2011.

External links
Wikimedia Commons has media related to Zodiacal light.

Reach, W. T. (1997). "The structured zodiacal light: IRAS, COBE, and ISO observations". Diffuse Infrared Radiation and the IRTS. ASP Conference Series. 124, 33–40
"Zodiacal Light and the Gegenschein", an essay by J. E. Littleton
Zodiacal Light and the False Dawn September 25, 2007
Zodiacal Light Over Laguna Verde October 29, 2009
Zodiacal light as seen from above the Himalayan Hills in Uttarakhand, India
Examples of zodiacal light descriptions in Islamic tradition, and their application

vte

Solar System
The Sun, the planets, their moons, and several trans-Neptunian objects

Sun Mercury Venus Earth Mars Ceres Jupiter Saturn Uranus Neptune Pluto Haumea Makemake Eris

Planets

Terrestrials
Mercury Venus Earth Mars Giants
Jupiter Saturn Uranus Neptune Dwarfs
Ceres Pluto Haumea Makemake Eris

Moons

Earth
Moon other near-Earth objects Mars
Phobos Deimos Jupiter
Ganymede Callisto Io Europa all 79 Saturn
Titan Rhea Iapetus Dione Tethys Enceladus Mimas Hyperion Phoebe all 82 Uranus
Titania Oberon Umbriel Ariel Miranda all 27 Neptune
Triton Proteus Nereid all 14 Pluto
Charon Nix Hydra Kerberos Styx Eris
Dysnomia Haumean
Hiʻiaka Namaka Makemake
S/2015 (136472) 1

Lists

Comets Possible dwarf planets Gravitationally rounded objects Minor planets Natural satellites Solar System models Solar System objects
by size by discovery date Interstellar and circumstellar molecules

Small
Solar
System
bodies

Comets Damocloids Meteoroids Minor planets
names and meanings moons Planetesimal Mercury-crossers Venus-crossers Venus trojans Near-Earth objects Earth-crossers Earth trojans Mars-crossers Mars trojans Asteroid belt Asteroids
Ceres Pallas Juno Vesta active first 1000 families exceptional Kirkwood gap Jupiter-crossers Jupiter trojans Centaurs Saturn-crossers Uranus-crossers Uranus trojans Neptune-crossers Cis-Neptunian objects
Centaurs Neptune trojans Trans-Neptunian objects
Kuiper belt
Cubewanos Plutinos Detached objects Sednoids Scattered disc Oort cloud Hills cloud


Rings

Jovian Saturnian (Rhean) Charikloan Chironean Uranian Neptunian Haumean

Hypothetical
objects

Fifth giant Nemesis Phaeton Planet Nine Planet V Planet X Subsatellites Theia Tyche Vulcan Vulcanoids

Exploration
(outline)

Discovery
astronomy historical models timeline Space probes
timeline list Human spaceflight
space stations list Mercury Venus Moon
mining Mars Ceres Asteroids
mining Comets Jupiter Saturn Uranus Neptune Pluto Deep space Colonization

Formation
and
evolution

Accretion Accretion disk
Excretion disk Circumplanetary disk Circumstellar disc Circumstellar envelope Coatlicue Cosmic dust Debris disk Detached Objects Disrupted planet EXCEDE Exozodiacal dust Extraterrestrial materials
Sample-return mission Sample curation Giant-impact hypothesis Gravitational collapse Hills Cloud Interplanetary dust cloud Interplanetary medium Interplanetary space Interstellar cloud Interstellar dust Interstellar medium Interstellar space Kuiper belt Merging stars Molecular cloud Nebular hypothesis Oort cloud Outer space Planetary migration Planetary system Planetesimal Planet formation Protoplanetary disk Ring system Rubble pile Scattered disc Star formation

Outline of the Solar System Solar system.jpg Solar System portal Crab Nebula.jpg Astronomy portal The Earth seen from Apollo 17 with transparent background.png Earth Sciences portal

Solar System → Local Interstellar Cloud → Local Bubble → Gould Belt → Orion Arm → Milky Way → Milky Way subgroup → Local Group → Local Sheet → Virgo Supercluster → Laniakea Supercluster → Observable universe → Universe
Each arrow (→) may be read as "within" or "part of".

Astronomy Encyclopedia

Physics Encyclopedia

World

Index

Hellenica World - Scientific Library

Retrieved from "http://en.wikipedia.org/"
All text is available under the terms of the GNU Free Documentation License