Theinterplanetary dust cloud, orzodiacal cloud (as the source of thezodiacal light), consists ofcosmic dust (smallparticles floating inouter space) that pervades the space betweenplanets withinplanetary systems, such as theSolar System.^[2] This system of particles has been studied for many years in order to understand its nature, origin, and relationship to larger bodies. There are several methods to obtainspace dust measurement.

In the Solar System, interplanetary dust particles have a role inscatteringsunlight and in emittingthermal radiation, which is the most prominent feature of thenight sky's radiation, with wavelengths ranging 5–50μm.^[3] Theparticle sizes of grains characterizing theinfrared emission nearEarth's orbit typically range 10–100 μm.^[4] Microscopic impact craters on lunar rocks returned by theApollo Program^[5] revealed the size distribution ofcosmic dust particles bombarding the lunar surface. The’’Grün’’ distribution of interplanetary dust at 1 AU,^[6] describes the flux ofcosmic dust from nm to mm sizes at 1 AU.

The total mass of the interplanetary dust cloud is approximately3.5×10¹⁶ kg, or the mass of anasteroid of radius 15 km (with density of about 2.5 g/cm³).^[7] Straddling thezodiac along theecliptic, this dust cloud is visible as the zodiacal light in a moonless and naturally dark sky and is best seen sunward during astronomicaltwilight.

ThePioneer spacecraft observations in the 1970s linked thezodiacal light with the interplanetary dust cloud in the Solar System.^[8] Also, theVBSDC instrument on theNew Horizons probe was designed to detect impacts of the dust from the zodiacal cloud in the Solar System.^[9]

The sources of interplanetary dust particles (IDPs) include at least: asteroid collisions,cometary activity and collisions in the inner Solar System,Kuiper belt collisions, andinterstellar medium grains (Backman, D., 1997). The origins of the zodiacal cloud have long been subject to one of the most heated controversies in the field of astronomy.

It was believed that IDPs had originated from comets or asteroids whose particles had dispersed throughout the extent of the cloud. However, further observations have suggested that Marsdust storms may be responsible for the zodiacal cloud's formation.^[10][2]

The main physical processes "affecting" (destruction or expulsion mechanisms) interplanetary dust particles are: expulsion byradiation pressure, inwardPoynting-Robertson (PR) radiation drag,solar wind pressure (with significant electromagnetic effects),sublimation, mutual collisions, and the dynamical effects of planets (Backman, D., 1997).

The lifetimes of these dust particles are very short compared to the lifetime of the Solar System. If one finds grains around a star that is older than about 10,000,000 years, then the grains must have been from recently released fragments of larger objects, i.e. they cannot be leftover grains from theprotoplanetary disk (Backman, private communication).^{[citation needed]} Therefore, the grains would be "later-generation" dust. The zodiacal dust in the Solar System is 99.9% later-generation dust and 0.1% intrudinginterstellar medium dust. All primordial grains from the Solar System's formation were removed long ago.

Particles which are affected primarily by radiation pressure are known as "beta meteoroids". They are generally less than 1.4 × 10⁻¹² g and are pushed outward from the Sun into interstellar space.^[11]

The interplanetary dust cloud has a complex structure (Reach, W., 1997). Apart from a background density, this includes:

• At least 8dust trails—their source is thought to beshort-period comets.
• A number of dust bands, the sources of which are thought to beasteroid families in themain asteroid belt. The three strongest bands arise from theThemis family, theKoronis family, and theEos family. Other source families include theMaria,Eunomia, and possibly theVesta and/orHygiea families (Reach et al. 1996).
• At least 2 resonant dust rings are known (for example, the Earth-resonant dust ring, although every planet in the Solar System is thought to have a resonant ring with a "wake") (Jackson and Zook, 1988, 1992) (Dermott, S.F. et al., 1994, 1997)

Interplanetary dust has been found to form rings of dust in the orbital space of Mercury and Venus.^[13] Venus's orbital dust ring is suspected to originate either from yet undetected Venus trailing asteroids,^[13] interplanetary dust migrating in waves from orbital space to orbital space, or from the remains of the Solar System'scircumstellar disc, out of which itsproto-planetary disc and then itself, the Solarplanetary system, formed.^[14]

In 1951,Fred Whipple predicted that micrometeorites smaller than 100 micrometers in diameter might be decelerated on impact with the Earth's upper atmosphere without melting.^[15] The modern era of laboratory study of these particles began with the stratospheric collection flights ofDonald E. Brownlee and collaborators in the 1970s using balloons and thenU-2 aircraft.^[16]

Although some of the particles found were similar to the material in present-day meteorite collections, thenanoporous nature and unequilibrated cosmic-average composition of other particles suggested that they began as fine-grained aggregates of nonvolatile building blocks and cometary ice.^[17][18] The interplanetary nature of these particles was later verified bynoble gas^[19] andsolar flare track^[20] observations.

In that context a program for atmospheric collection and curation of these particles was developed atJohnson Space Center in Texas.^[21] This stratospheric micrometeorite collection, along withpresolar grains from meteorites, are unique sources ofextraterrestrial material (not to mention being small astronomical objects in their own right) available for study in laboratories today.

Spacecraft that have carried dust detectors includeHelios,Pioneer 10,Pioneer 11,Ulysses (heliocentric orbit out to the distance of Jupiter),Galileo (Jupiter Orbiter),Cassini (Saturn orbiter), andNew Horizons (seeVenetia Burney Student Dust Counter).

The Solar interplanetary dust cloud obscures theextragalactic background light, making observations of it from theInner Solar System very limited.^[12]

Collections of review articles on various aspects of interplanetary dust and related fields appeared in the following books:

In 1978Tony McDonnell edited the bookCosmic Dust^[22] which contained chapters^[23] on comets along with zodiacal light as indicator of interplanetary dust, meteors, interstellar dust, microparticle studies by sampling techniques, and microparticle studies by space instrumentation. Attention is also given to lunar and planetary impact erosion, aspects of particle dynamics, and acceleration techniques and high-velocity impact processes employed for the laboratory simulation of effects produced by micrometeoroids.

2001Eberhard Grün, Bo Gustafson, Stan Dermott, and Hugo Fechtig published the bookInterplanetary Dust.^[24] Topics covered^[25] are: historical perspectives; cometary dust; near-Earth environment; meteoroids and meteors; properties of interplanetary dust, information from collected samples; in situ measurements of cosmic dust; numerical modeling of the Zodiacal Cloud structure; synthesis of observations; instrumentation; physical processes; optical properties of interplanetary dust; orbital evolution of interplanetary dust; circumplanetary dust, observations and simple physics; interstellar dust and circumstellar dust disks.

2019 Rafael Rodrigo, Jürgen Blum, Hsiang-Wen Hsu, Detlef V. Koschny,Anny-Chantal Levasseur-Regourd, Jesús Martín-Pintado, Veerle J. Sterken, and Andrew Westphal collected reviews in the bookCosmic Dust from the Laboratory to the Stars.^[26] Included are discussions^[27] of dust in various environments: from planetary atmospheres and airless bodies over interplanetary dust, meteoroids, comet dust and emissions from active moons to interstellar dust and protoplanetary disks. Diverse research techniques and results, including in-situ measurement, remote observation, laboratory experiments and modelling, and analysis of returned samples are discussed.

• Circumstellar disk
• Cosmic dust
• Interplanetary medium
• Martian soil
• Dust storms on Mars
• Micrometeoroid
• Exozodiacal dust
• Zodiacal light

• Jackson A.A.; Zook, H.A. (1988)."A Solar System Dust Ring with the Earth as its Shepherd".Nature.337 (6208):629–631.Bibcode:1989Natur.337..629J.doi:10.1038/337629a0.S2CID 4351090.
• Jackson A.A.; Zook, H.A. (1992)."Orbital evolution of dust particles from comets and asteroids".Icarus.97 (1):70–84.Bibcode:1992Icar...97...70J.doi:10.1016/0019-1035(92)90057-E.
• May, Brian Harold (2008).A Survey of Radial Velocities in the Zodiacal Dust Cloud(PhD thesis). New York: Springer.hdl:10044/1/1333.ISBN 978-0-387-77705-4.
• Backman, Dana (1997). "Exozody Workshop, NASA-Ames, October 23–25, 1997".Extrasolar Zodiacal Emission - NASA Study Panel Report.
• NASA Panel Report on Extrasolar Zodiacal Emission
• Dermott, S.F.; Jayaraman, S.; Xu, Y.L.; Gustafson, A.A.S.; Liou, J.C. (30 June 1994). "A circumsolar ring of asteroid dust in resonant lock with the Earth".Nature.369 (6483):719–23.Bibcode:1994Natur.369..719D.doi:10.1038/369719a0.S2CID 4345910.
• Dermott, S.F. (1997). "Signatures of Planets in Zodiacal Light".Extrasolar Zodiacal Emission - NASA Study Panel Report.
• Levasseur-Regourd, A.C. (1996). "Optical and Thermal Properties of Zodiacal Dust".Physics, Chemistry and Dynamics of Interplanetary Dust, ASP Conference series, Vol 104. pp. 301–.
• Reach, W. (1997). "General Structure of the Zodiacal Dust Cloud".Extrasolar Zodiacal Emission - NASA Study Panel Report.
• Reach, W.T.; Franz, B.A.; Weiland, J.L. (1997). "The Three-Dimensional Structure of the Zodiacal Dust Bands".Icarus.127 (2):461–484.Bibcode:1997Icar..127..461R.doi:10.1006/icar.1997.5704.

• Cosmic dust
• Solar System
• Planetary science
• Outer space

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