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Depolarizer (optics)

April 26, 2024

A depolarizer or depolariser is an optical device used to scramble the polarization of light. An ideal depolarizer would output randomly polarized light whatever its input, but all practical depolarizers produce pseudo-random output polarization.

Optical systems are often sensitive to the polarization of light reaching them (for example grating-based spectrometers). Unwanted polarization of the input to such a system may cause errors in the system's output.

Types edit

Cornu depolarizer edit

 
Cornu depolarizer

The Cornu depolarizer was one of the earliest designs, named after its inventor Marie Alfred Cornu. It consists of a pair of 45° prisms of quartz crystal, optically contacted to form a cuboid. The fast axes are 90° apart and 45° from the sides of the depolarizer (see figure). Any ray entering the prism effectively passes through two wave plates. The thickness of these wave plates and therefore their retardance varies across the beam. The phase shift is given by[1]

 

For an input beam of uniform polarization the output polarization will be periodic in y. The phase shift is also dependent on wavelength due to dispersion.

The use of two prisms means that the output is essentially coaxial with the input. At the interface between the prisms refraction does take place, as the refractive indices are exchanged. There is therefore some separation of the components of the output beam.

This device is not commonly used today, but similar designs are commercially available.

Lyot depolarizer edit

 
Lyot depolarizer

The Lyot depolarizer is another early design. It was invented by Bernard Lyot. It consists of two wave plates with their fast axes 45° apart, with the second plate twice as thick as the first. The output is periodic as a function of wavelength and as a function of the wave-plates' thicknesses. Special considerations are needed when this depolarizer is to be used for a particular application, because the optimal wave-plate thicknesses depend on the signal wavelength and optical spectrum with which it is to be used. It is commercially available for broadband visible applications.

This device is especially attractive in fiber optics, where two pieces of correct length of polarization-maintaining optical fiber spliced together at a 45° angle are used instead of the wave-plates, thus no other components such as beam splitters are required.

Wedge depolarizer edit

Quartz-silica edit

 
Quartz-silica wedge depolarizer

The quartz-silica wedge depolarizer is a common commercial design and is similar to the Cornu depolarizer, however, the angle between the two components is much smaller (2° is typical) and only the first component is birefringent. The second component is made of fused silica, which has a very similar refractive index to quartz, but is not birefringent. The fast axis of the quartz element is generally at 45° to the wedge. The whole device is much more compact than a Cornu depolarizer (for the same aperture).

As with the Cornu depolarizer, there is some separation of the output as a function of polarization, as well as some beam deviation due to the imperfect match in refractive index between quartz and silica. The output is periodic across the depolarizer. Because the wedge angle is so much smaller than in a Cornu depolarizer the period is larger, often around 6 mm. This depolarizer also has a preferred orientation because of its single defined fast axis. In commercial wedge depolarizers this is usually marked.

Quartz-quartz edit

Quartz-quartz wedge depolarizers are commercially available, though not common. They are similar to Cornu depolarizers, but with the small wedge angle of the silica-compensated wedge.

Other birefringent materials can be used in place of quartz in the above designs.

Wedge depolarizers exhibit some small beam deviation. This is true even if the faces of the optic are exactly parallel. Because each half of the optic is a wedge, and the two halves do not have exactly the same refractive index (for a particular polarization), the depolarizer is effectively very slightly wedged (optically).

Time-variable depolarizer edit

The Lyot depolarizer and similar devices are based on the fact that the retardations of optical waveplates or retarders depend on optical frequency or wavelength. They cause polarization mode dispersion which can be detrimental. Furthermore they cannot be used for (quasi-)monochromatic signals. For the latter, time-variable depolarizers are needed. These are composed of time-variable optical retarders. An effective way to realize time-variable depolarizers are rotating waveplates or equivalent optical devices.

A rotating halfwave plate produces polarization which is periodic in time, and therefore effectively scrambled for sufficiently slow responses. Its input polarization must be linear. Resulting output polarization is rotating linear polarization. Likewise, circular polarization can be depolarized with a rotating quarterwave plate. Output polarization is again linear. If a halfwave and a quarterwave plate are concatenated and rotate at different speeds, any input polarization is depolarized. If the waveplates are not perfect, more rotating waveplates can improve performance.[2] Based on electrooptic rotating waveplates, such polarization-independent depolarizers are commercially available with depolarization intervals down to 360 ns.

Other ways to produce depolarized light edit

In many applications it is possible to use a quarter-wave plate to produce circularly polarized light, but this is only possible for light of a limited range of wavelengths which is linearly polarized to start with. Other methods have been demonstrated, such as the use of Faraday rotators and liquid crystals.[3] It is also possible to depolarize light using fiber optics. Relatively high degree of depolarization is also achieved by light passing through usual semitransparent materials like matte plastic or greased paper.

See also edit

References edit

  1. ^ Norman Hodgson, Horst Weber (2005). Laser Resonators and Beam Propagation: Fundamentals, Advanced Concepts and Applications (Second ed.). Springer. p. Chapter 3. ISBN 978-0-387-40078-5.
  2. ^ Noe, Reinhold; Koch, Benjamin (2019-01-25). "Accuracy Limits of Polarization-Independent Optical Depolarizers Based on Rotating Waveplates". arXiv:1901.08838 [eess.SP].
  3. ^ Diorio, Nicholas J.; Fisch, Michael R.; West, John L. (2001-10-15). "Filled liquid crystal depolarizers". Journal of Applied Physics. 90 (8). AIP Publishing: 3675–3678. Bibcode:2001JAP....90.3675D. doi:10.1063/1.1401799. ISSN 0021-8979.

External links edit

  • "Polarization-independent depolarizer and 50 Mrad/s polarization scrambler". Novoptel.

April 26, 2024
depolarizer, optics, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, depolarizer, optics, news, newspapers, books, s. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Depolarizer optics news newspapers books scholar JSTOR July 2023 Learn how and when to remove this template message A depolarizer or depolariser is an optical device used to scramble the polarization of light An ideal depolarizer would output randomly polarized light whatever its input but all practical depolarizers produce pseudo random output polarization Optical systems are often sensitive to the polarization of light reaching them for example grating based spectrometers Unwanted polarization of the input to such a system may cause errors in the system s output Contents 1 Types 1 1 Cornu depolarizer 1 2 Lyot depolarizer 1 3 Wedge depolarizer 1 3 1 Quartz silica 1 3 2 Quartz quartz 1 4 Time variable depolarizer 2 Other ways to produce depolarized light 3 See also 4 References 5 External linksTypes editCornu depolarizer edit nbsp Cornu depolarizer The Cornu depolarizer was one of the earliest designs named after its inventor Marie Alfred Cornu It consists of a pair of 45 prisms of quartz crystal optically contacted to form a cuboid The fast axes are 90 apart and 45 from the sides of the depolarizer see figure Any ray entering the prism effectively passes through two wave plates The thickness of these wave plates and therefore their retardance varies across the beam The phase shift is given by 1 d y 2 p l n 2 n 1 2 y a displaystyle delta y frac 2 pi lambda n 2 n 1 2y a nbsp For an input beam of uniform polarization the output polarization will be periodic in y The phase shift is also dependent on wavelength due to dispersion The use of two prisms means that the output is essentially coaxial with the input At the interface between the prisms refraction does take place as the refractive indices are exchanged There is therefore some separation of the components of the output beam This device is not commonly used today but similar designs are commercially available Lyot depolarizer edit nbsp Lyot depolarizer The Lyot depolarizer is another early design It was invented by Bernard Lyot It consists of two wave plates with their fast axes 45 apart with the second plate twice as thick as the first The output is periodic as a function of wavelength and as a function of the wave plates thicknesses Special considerations are needed when this depolarizer is to be used for a particular application because the optimal wave plate thicknesses depend on the signal wavelength and optical spectrum with which it is to be used It is commercially available for broadband visible applications This device is especially attractive in fiber optics where two pieces of correct length of polarization maintaining optical fiber spliced together at a 45 angle are used instead of the wave plates thus no other components such as beam splitters are required Wedge depolarizer edit Quartz silica edit nbsp Quartz silica wedge depolarizer The quartz silica wedge depolarizer is a common commercial design and is similar to the Cornu depolarizer however the angle between the two components is much smaller 2 is typical and only the first component is birefringent The second component is made of fused silica which has a very similar refractive index to quartz but is not birefringent The fast axis of the quartz element is generally at 45 to the wedge The whole device is much more compact than a Cornu depolarizer for the same aperture As with the Cornu depolarizer there is some separation of the output as a function of polarization as well as some beam deviation due to the imperfect match in refractive index between quartz and silica The output is periodic across the depolarizer Because the wedge angle is so much smaller than in a Cornu depolarizer the period is larger often around 6 mm This depolarizer also has a preferred orientation because of its single defined fast axis In commercial wedge depolarizers this is usually marked Quartz quartz edit Quartz quartz wedge depolarizers are commercially available though not common They are similar to Cornu depolarizers but with the small wedge angle of the silica compensated wedge Other birefringent materials can be used in place of quartz in the above designs Wedge depolarizers exhibit some small beam deviation This is true even if the faces of the optic are exactly parallel Because each half of the optic is a wedge and the two halves do not have exactly the same refractive index for a particular polarization the depolarizer is effectively very slightly wedged optically Time variable depolarizer edit The Lyot depolarizer and similar devices are based on the fact that the retardations of optical waveplates or retarders depend on optical frequency or wavelength They cause polarization mode dispersion which can be detrimental Furthermore they cannot be used for quasi monochromatic signals For the latter time variable depolarizers are needed These are composed of time variable optical retarders An effective way to realize time variable depolarizers are rotating waveplates or equivalent optical devices A rotating halfwave plate produces polarization which is periodic in time and therefore effectively scrambled for sufficiently slow responses Its input polarization must be linear Resulting output polarization is rotating linear polarization Likewise circular polarization can be depolarized with a rotating quarterwave plate Output polarization is again linear If a halfwave and a quarterwave plate are concatenated and rotate at different speeds any input polarization is depolarized If the waveplates are not perfect more rotating waveplates can improve performance 2 Based on electrooptic rotating waveplates such polarization independent depolarizers are commercially available with depolarization intervals down to 360 ns Other ways to produce depolarized light editIn many applications it is possible to use a quarter wave plate to produce circularly polarized light but this is only possible for light of a limited range of wavelengths which is linearly polarized to start with Other methods have been demonstrated such as the use of Faraday rotators and liquid crystals 3 It is also possible to depolarize light using fiber optics Relatively high degree of depolarization is also achieved by light passing through usual semitransparent materials like matte plastic or greased paper See also editPolarization scrambling Polarizer Optical prismsReferences edit Norman Hodgson Horst Weber 2005 Laser Resonators and Beam Propagation Fundamentals Advanced Concepts and Applications Second ed Springer p Chapter 3 ISBN 978 0 387 40078 5 Noe Reinhold Koch Benjamin 2019 01 25 Accuracy Limits of Polarization Independent Optical Depolarizers Based on Rotating Waveplates arXiv 1901 08838 eess SP Diorio Nicholas J Fisch Michael R West John L 2001 10 15 Filled liquid crystal depolarizers Journal of Applied Physics 90 8 AIP Publishing 3675 3678 Bibcode 2001JAP 90 3675D doi 10 1063 1 1401799 ISSN 0021 8979 External links edit Polarization independent depolarizer and 50 Mrad s polarization scrambler Novoptel Retrieved from https en wikipedia org w index php title Depolarizer optics amp oldid 1172351058 Lyot depolarizer, wikipedia, wiki, book, books, library,

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