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{{multiple image
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| image1 = Circular.Polarization.Circularly.Polarized.Light_Without.Components_Right.Handed.svg
| image2 = Circular.Polarization.Circularly.Polarized.Light_With.Components_Right.Handed.svg
| image3 = Circular polarization cross section.gif
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In a circularly polarized electromagnetic wave, the individual electric field vectors, as well as their combined vector, have a constant [[Magnitude (vector)|magnitude]], and with changing phase angle. Given that this is a [[plane wave]], each vector represents the magnitude and direction of the electric field for an entire plane that is perpendicular to the optical axis. Specifically, given that this is a [[Plane wave#Polarized electromagnetic plane waves|circularly polarized plane wave]], these vectors indicate that the electric field, from plane to plane, has a constant strength while its direction steadily rotates. Refer to [[
Circular polarization is often encountered in the field of optics and, in this section, the electromagnetic wave will be simply referred to as [[light]].
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The handedness of polarized light is reversed reflected off a surface at normal incidence. Upon such reflection, the rotation of the [[plane of polarization]] of the reflected light is identical to that of the incident field. However, with propagation now in the ''opposite'' direction, the same rotation direction that would be described as "right-handed" for the incident beam, is "left-handed" for propagation in the reverse direction, and vice versa. Aside from the reversal of handedness, the ellipticity of polarization is also preserved (except in cases of reflection by a [[Birefringence|birefringent]] surface).
Note that this principle only holds strictly for light reflected at normal incidence. For instance, right circularly polarized light reflected from a dielectric surface at grazing incidence (an angle beyond the [[Brewster's angle|Brewster angle]]) will still emerge as right-handed, but elliptically
[[File:Reversal of handedness of circularly polarized light reflected by mirror 2s.gif|thumbnail|A 3-slide series of pictures taken with and without a pair of MasterImage 3D circularly polarized movie glasses of some dead European rose chafers (Cetonia aurata) whose shiny green color comes from left-polarized light. Note that, without glasses, both the beetles and their images have shiny color. The right-polarizer removes the color of the beetles but leaves the color of the images. The left-polarizer does the opposite, showing reversal of handedness of the reflected light.]]
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The archive of the [https://web.archive.org/web/20090822015912/http://www.its.bldrdoc.gov/fs-1037/ US Federal Standard 1037C] proposes two contradictory conventions of handedness.<ref>In one ___location it is stated..."Note 1. ... In general, the figure, i.e., polarization, is elliptical and is traced in a clockwise or anti-clockwise sense, as viewed in the direction of propagation. ... Rotation of the electric vector in a clockwise sense is designated right-hand polarization, and rotation in an anti-clockwise sense is designated left-hand polarization. "[http://www.its.bldrdoc.gov/fs-1037//dir-028/_4059.htm] {{Webarchive|url=https://web.archive.org/web/20110514080812/http://www.its.bldrdoc.gov/fs-1037/dir-028/_4059.htm|date=2011-05-14}} In another ___location it is stated... "Note 4: Circular polarization may be referred to as "right-hand" or "left-hand", depending on whether the helix describes the thread of a right-hand or left-hand screw, respectively". [http://www.its.bldrdoc.gov/fs-1037/dir-007/_0972.htm] {{Webarchive|url=https://web.archive.org/web/20110606113103/http://www.its.bldrdoc.gov/fs-1037/dir-007/_0972.htm|date=2011-06-06}}</ref>
Note that the IEEE defines RHCP and LHCP the opposite as those used by physicists. The IEEE 1979 Antenna Standard will show RHCP on the South Pole of the Poincare Sphere. The IEEE defines RHCP using the right hand with thumb pointing in the direction of transmit, and the fingers showing the direction of rotation of the E field with time. The rationale for the opposite conventions used by Physicists and Engineers is that Astronomical Observations are always done with the incoming wave traveling toward the observer, where as for most engineers, they are assumed to be standing behind the transmitter watching the wave traveling away from them. This article is not using the IEEE 1979 Antenna Standard and is not using the +t convention typically used in IEEE work.
== FM radio ==
[[File:KHTB-FM broadcasting antennas LakeMountain.jpg|thumb|upright=0.6|Crossed-dipole antenna array of station [[KENZ (FM)|KENZ]]'s {{nowrap|94.9 MHz}}, {{nowrap|48 kW}} transmitter on Lake Mountain, Utah. It radiates circularly polarized radio waves.]]
[[FM broadcasting|FM broadcast]] radio stations sometimes employ circular polarization to improve signal penetration into buildings and vehicles. It is one example of what the [[International Telecommunication Union]] refers to as "mixed polarization", i.e. radio emissions that include both horizontally- and vertically-polarized components.<ref>{{cite report |title=Report 464-5, "Polarization of Emissions in Frequency-Modulation Broadcasting in Band 8 (VHF)" |year=1990 |url=https://www.itu.int/dms_pub/itu-r/opb/rep/r-rep-bs.464-5-1990-pdf-e.pdf |publisher=International Telecommunications Union}}</ref> In the United States, [[Federal Communications Commission]] regulations state that horizontal polarization is the standard for FM broadcasting, but that "circular or elliptical polarization may be employed if desired".<ref>{{CodeFedReg |47|73|316}}</ref>
==Dichroism==
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==Antennas==
{{Over-quotation|section|date=April 2018}}
A number of different types of antenna elements can be used to produce circularly polarized (or nearly so) radiation; following [[Constantine A. Balanis|Balanis]],<ref name=Balanis>Balanis, Constantine A. "Antenna Theory
<blockquote>"... two crossed dipoles provide the two orthogonal field components.... If the two dipoles are identical, the field intensity of each along zenith ... would be of the same intensity. Also, if the two dipoles were fed with a 90° degree time-phase difference (phase quadrature), the polarization along zenith would be circular.... One way to obtain the 90° time-phase difference between the two orthogonal field components, radiated respectively by the two dipoles, is by feeding one of the two dipoles with a transmission line which is 1/4 wavelength longer or shorter than that of the other," p.80;</blockquote>
or [[Helical antenna|''helical elements'']]:
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==In quantum mechanics==
{{further|Photon polarization}}
In the [[quantum mechanical]] view, light is composed of [[photons]]. Polarization is a manifestation of the [[spin angular momentum of light]]. More specifically, in quantum mechanics, the direction of spin of a photon is tied to the handedness of the circularly polarized light, and the spin of a beam of photons is similar to the spin of a beam of particles, such as electrons.<ref>Introduction to Quantum Theory 2ED David Park Sec 2.2 Pg32 "... the polarization of a beam of light is exactly the same kind of thing as the spin of a beam of electrons, the differences of terminology reflecting only the accidents of the historical order of discovery."</ref> In the [[physics]] convention (from the point of view of the source), a right-handed circular polarization corresponds to a positive spin (denoted <math>\sigma^+</math>), whereas a left-handed circular polarization corresponds to a negative spin (denoted <math>\sigma^-</math>).<ref>W. Demtröder, [https://emineter.wordpress.com/wp-content/uploads/2015/03/atoms-molecules-and-photons-demtrc3b6der-springer-2005.pdf "Atoms, molecules and photons"], 2006, Springer, sec. 3.1, p. 91. The author uses the optics convention. "If left circularly-
polarized light (σ+-polarization) propagating in the z
direction is absorbed by atoms, the z component of
their angular momentum Jz is changed by ∆Jz = +ℏ". </ref>
==In nature==
[[File:Cetonia-aurata.jpg|thumb|right|The [[Cetonia aurata|rose chafer]]'s external surface reflects almost exclusively left-circularly polarized light.]]
Only a few mechanisms in nature are known to systematically produce circularly polarized [[light]]. In 1911, [[Albert A. Michelson|Albert Abraham Michelson]] discovered that light reflected from the golden scarab beetle ''[[Chrysina resplendens]]'' is preferentially left-polarized. Since then, circular polarization has been measured in several other [[Scarabaeidae|scarab beetles]] such as ''[[Chrysina gloriosa]]'',<ref>{{Cite journal|url=https://www.science.org/doi/10.1126/science.1172051|title=Structural Origin of Circularly Polarized Iridescence in Jeweled Beetles|first1=Mohan|last1=Srinivasarao|first2=Jung Ok|last2=Park|first3=Matija|last3=Crne|first4=Vivek|last4=Sharma|date=July 24, 2009|journal=Science|volume=325|issue=5939|pages=449–451|via=science.sciencemag.org|doi=10.1126/science.1172051|pmid=19628862|bibcode=2009Sci...325..449S|s2cid=206519071|url-access=subscription}}</ref> as well as some [[crustacean]]s such as the [[mantis shrimp]]. In these cases, the underlying mechanism is the molecular-level helicity of the [[chitin]]ous [[cuticle]].<ref name="Hegedüs">{{cite journal |title=Imaging polarimetry of the circularly polarizing cuticle of scarab beetles (Coleoptera: Rutelidae, Cetoniidae) |author1=Hegedüs, Ramón |author2=Győző Szélb |author3=Gábor Horváth |doi=10.1016/j.visres.2006.02.007 |journal=Vision Research |volume=46 |issue=17 |date=September 2006 |pages=2786–2797 |pmid=16564066 |s2cid=14974820 |doi-access=free }}</ref>
The [[bioluminescence]] of the [[larva]]e of [[firefly|fireflie]]s is also circularly polarized, as reported in 1980 for the species ''[[Photuris|Photuris lucicrescens]]'' and ''[[Photuris versicolor]]''. For fireflies, it is more difficult to find a microscopic explanation for the polarization, because the left and right lanterns of the larvae were found to emit polarized light of opposite senses. The authors suggest that the light begins with a [[linear polarization]] due to inhomogeneities inside aligned [[photocyte]]s, and it picks up circular polarization while passing through linearly [[Birefringence|birefringent]] tissue.<ref>{{cite journal |title=Circular polarization observed in bioluminescence |author1=Wynberg, Hans |author2=Meijer, E.W. |author3=Hummelen, J.C. |author4=Dekkers, H.P.J.M. |author5=Schippers, P.H. |author6=Carlson, A.D. |url=http://keur.eldoc.ub.rug.nl/FILES/wetenschappers/10/29/29.pdf |journal=Nature |volume=286 |issue=5773 |pages=641–642 |date=7 August 1980 |doi=10.1038/286641a0 |bibcode=1980Natur.286..641W |s2cid=4324467 |url-status=dead |archive-url=https://web.archive.org/web/20110724164914/http://keur.eldoc.ub.rug.nl/FILES/wetenschappers/10/29/29.pdf |archive-date=24 July 2011 }}</ref>
Circular polarization has been detected in light reflected from leaves and photosynthetic microbes.<ref name="b966">{{cite journal | last1=Sparks | first1=William B. | last2=Hough | first2=James | last3=Germer | first3=Thomas A. | last4=Chen | first4=Feng | last5=DasSarma | first5=Shiladitya | last6=DasSarma | first6=Priya | last7=Robb | first7=Frank T. | last8=Manset | first8=Nadine | last9=Kolokolova | first9=Ludmilla | last10=Reid | first10=Neill | last11=Macchetto | first11=F. Duccio | last12=Martin | first12=William | title=Detection of circular polarization in light scattered from photosynthetic microbes | journal=Proceedings of the National Academy of Sciences | volume=106 | issue=19 | date=2009-05-12 | issn=0027-8424 | pmid=19416893 | pmc=2674403 | doi=10.1073/pnas.0810215106 | pages=7816–7821| doi-access=free | arxiv=0904.4646 | bibcode=2009PNAS..106.7816S }}</ref>
Water-air interfaces provide another source of circular polarization. Sunlight that gets scattered back up towards the surface is linearly polarized. If this light is then [[total internal reflection|totally internally reflected]] back down, its vertical component undergoes a phase shift. To an underwater observer looking up, the faint light outside [[Snell's window]] therefore is (partially) circularly polarized.<ref>{{cite book |title=Polarized Light in Animal Vision: Polarization Patterns in Nature |author1=Horváth, Gábor |author2=Dezsö Varjú |year=2003 |publisher=Springer |isbn=978-3-540-40457-6 |pages=100–103}}</ref>
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Weaker sources of circular polarization in nature include multiple scattering by linear polarizers{{dubious|date=June 2021}}, as in the circular polarization of starlight, and selective absorption by [[circular dichroism|circularly dichroic]] media.
Radio emission from pulsars can be strongly circularly polarized.<ref>{{cite journal|doi=10.1111/j.1365-2966.2005.09681.x |title=On the origin of the circular polarization in radio pulsars |date=2005 |last1=Gogoberidze |first1=G. |last2=Machabeli |first2=G. Z. |journal=Monthly Notices of the Royal Astronomical Society |volume=364 |issue=4 |pages=1363–1366 |doi-access=free |arxiv=astro-ph/0510116 |bibcode=2005MNRAS.364.1363G }}</ref>
Two species of [[mantis shrimp]] have been reported to be able to detect circular polarized light.<ref>{{cite journal|author1=Tsyr-Huei Chiou |author2=Sonja Kleinlogel |author3=Tom Cronin |author4=Roy Caldwell |author5=Birte Loeffler |author6=Afsheen Siddiqi |author7=Alan Goldizen |author8=Justin Marshall |title=Circular polarization vision in a stomatopod crustacean |journal=[[Current Biology]] |year=2008 |volume=18 |issue=6 |pages=429–34 |doi=10.1016/j.cub.2008.02.066 |pmid=18356053|s2cid=6925705 |doi-access=free |bibcode=2008CBio...18..429C }}</ref><ref name="Kleinlogel et al.">{{cite journal |author1=Sonja Kleinlogel |author2=Andrew White |title=The secret world of shrimps: polarisation vision at its best |journal=[[PLoS ONE]] |year=2008 |doi=10.1371/journal.pone.0002190 |volume=3 |issue=5 |pages=e2190 |pmid=18478095 |pmc=2377063 |bibcode=2008PLoSO...3.2190K|arxiv = 0804.2162 |doi-access=free }}</ref>
==See also==
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{{DEFAULTSORT:Circular Polarization}}
[[Category:Concepts in astrophysics]]
[[Category:Polarization (waves)]]
[[Category:Stellar astronomy]]
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