Cladding (fiber optics)

Last updated January 17, 2025

Cladding in optical fibers is one or more layers of materials of lower refractive index in intimate contact with a core material of higher refractive index.

The cladding causes light to be confined to the core of the fiber by total internal reflection at the boundary between the core and cladding.^[1] Light propagation within the cladding is typically suppressed for most fibers. However, some fibers can support cladding modes in which light propagates through the cladding as well as the core. Depending upon the quantity of modes that are supported, they are referred to as multi-mode fibers and single-mode fibers.^[2] Improving transmission through fibers by applying a cladding was discovered in 1953 by Dutch scientist Bram van Heel.^[3]

History

The fact that transmission through fibers could be improved by applying a cladding was discovered in 1953 by van Heel, who used it to demonstrate image transmission through a bundle of optical fibers.^[4] Early cladding materials included oils, waxes, and polymers. Lawrence E. Curtiss at the University of Michigan developed the first glass cladding in 1956, by inserting a glass rod into a tube of glass with a lower refractive index, fusing the two together, and drawing the composite structure into an optical fiber.^[4]

Modes

A cladding mode is a mode that is confined to the cladding of an optical fiber by virtue of the fact that the cladding has a higher refractive index than the surrounding medium, which is either air or the primary polymer overcoat.^[5] These modes are generally undesired. Modern fibers have a primary polymer overcoat with a refractive index that is slightly higher than that of the cladding, so that light propagating in the cladding is rapidly attenuated and disappears after only a few centimeters of propagation. An exception to this is double-clad fiber, which is designed to support a mode in its inner cladding, as well as one in its core.^[6]

Advantages

In the production of glass fibers, there will inevitably be surface irregularities (ex. pore and cracks) that will scatter light when struck and lessen the total travel distance of the light. The inclusion of a glass cladding greatly reduces the attenuation caused by these surface irregularities. This is due to the light scattering less at the glass/glass interface than it would have at the glass/air interface for a fiber without cladding.^[2] The two primary factors that allow for this are the smaller change in index of refraction seen between two surfaces of glass, as well as surface irregularities on the cladding not interfering with the light beams. The inclusion of glass cladding is also an improvement over just applying a polymer coating, as glass will typically be stronger, more homogenous, and cleaner. Additionally, the inclusion of a cladding layer also allows for the usage of smaller glass fiber cores.^[4] With most glass fibers have a cladding that raises the total outer diameter to 125 microns.^[7]

Effect on numerical aperture

The numerical aperture of a multimode optical fiber is a function of the indices of refraction of the cladding and the core:

{\rm {{NA}={\sqrt {n_{\rm {core}}^{2}-n_{\rm {clad}}^{2}}}}}

The numerical aperture allows for the calculation of the acceptance angle of incidence at the fiber interface.^[5] Which will give the maximum angle at which the incidence light can enter the core and maintain total internal reflection:

${\rm {{NA}=\sin(\theta _{A})}}$

By combining both of these equations it can be seen in the diagram above how $\theta _{A}$ is a function of $n_{1}$ and $n_{2}$ , where $n_{1}$ is the index of refraction of the core and $n_{2}$

$n_{2}$ is the index of refraction of the cladding.^[7]

Recent developments

Due to the relatively greater transmission of light they offer, fiber optic cores and claddings are usually made from highly purified silica glass. Certain impurities can be added to impart various properties, such as increasing transmission distance or improving fiber flexibility.^[8] There has been significant work done in improving these properties within the last several years.

Related Research Articles

$<span class="mw-page-title-main">Refraction</span> Physical phenomenon relating to the direction of waves$

In physics, refraction is the redirection of a wave as it passes from one medium to another. The redirection can be caused by the wave's change in speed or by a change in the medium. Refraction of light is the most commonly observed phenomenon, but other waves such as sound waves and water waves also experience refraction. How much a wave is refracted is determined by the change in wave speed and the initial direction of wave propagation relative to the direction of change in speed.

A guided ray is a ray of light in a multi-mode optical fiber, which is confined by the core.

In optics, the numerical aperture (NA) of an optical system is a dimensionless number that characterizes the range of angles over which the system can accept or emit light. By incorporating index of refraction in its definition, NA has the property that it is constant for a beam as it goes from one material to another, provided there is no refractive power at the interface. The exact definition of the term varies slightly between different areas of optics. Numerical aperture is commonly used in microscopy to describe the acceptance cone of an objective, and in fiber optics, in which it describes the range of angles within which light that is incident on the fiber will be transmitted along it.

Refractive index contrast, in an optical waveguide, such as an optical fiber, is a measure of the relative difference in refractive index of the core and cladding. The refractive index contrast, Δ, is often given by $, where n1 is the maximum refractive index in the core and n2 is the refractive index of the cladding. The criterion n2 < n1 must be satisfied in order to sustain a guided mode by total internal reflection. Alternative formulations include and . Normal optical fibers, constructed of different glasses, have very low refractive index contrast (Δ<<1) and hence are weakly-guiding. The weak guiding will cause a greater portion of the cross-sectional Electric field profile to reside within the cladding as compared to strongly-guided waveguides. Integrated optics can make use of higher core index to obtain Δ>1 allowing light to be efficiently guided around corners on the micro-scale, where popular high-Δ material platform is silicon-on-insulator. High-Δ allows sub-wavelength core dimensions and so greater control over the size of the evanescent tails. The most efficient low-loss optical fibers require low Δ to minimise losses to light scattered outwards.$

In fiber-optic communication, a single-mode optical fiber (SMF), also known as fundamental- or mono-mode, is an optical fiber designed to carry only a single mode of light - the transverse mode. Modes are the possible solutions of the Helmholtz equation for waves, which is obtained by combining Maxwell's equations and the boundary conditions. These modes define the way the wave travels through space, i.e. how the wave is distributed in space. Waves can have the same mode but have different frequencies. This is the case in single-mode fibers, where we can have waves with different frequencies, but of the same mode, which means that they are distributed in space in the same way, and that gives us a single ray of light. Although the ray travels parallel to the length of the fiber, it is often called transverse mode since its electromagnetic oscillations occur perpendicular (transverse) to the length of the fiber. The 2009 Nobel Prize in Physics was awarded to Charles K. Kao for his theoretical work on the single-mode optical fiber. The standards G.652 and G.657 define the most widely used forms of single-mode optical fiber.

$<span class="mw-page-title-main">Step-index profile</span> Refractive index profile in optical fibre$

For an optical fiber, a step-index profile is a refractive index profile characterized by a uniform refractive index within the core and a sharp decrease in refractive index at the core-cladding interface so that the cladding is of a lower refractive index. The step-index profile corresponds to a power-law index profile with the profile parameter approaching infinity. The step-index profile is used in most single-mode fibers and some multimode fibers.

Dispersion is the phenomenon in which the phase velocity of a wave depends on its frequency. Sometimes the term chromatic dispersion is used to refer to optics specifically, as opposed to wave propagation in general. A medium having this common property may be termed a dispersive medium.

All-silica fiber, or silica-silica fiber, is an optical fiber whose core and cladding are made of silica glass. The refractive index of the core glass is higher than that of the cladding. These fibers are typically step-index fibers. The cladding of an all-silica fiber should not be confused with the polymer overcoat of the fiber.

In electromagnetics, an evanescent field, or evanescent wave, is an oscillating electric and/or magnetic field that does not propagate as an electromagnetic wave but whose energy is spatially concentrated in the vicinity of the source. Even when there is a propagating electromagnetic wave produced, one can still identify as an evanescent field the component of the electric or magnetic field that cannot be attributed to the propagating wave observed at a distance of many wavelengths.

In the field of optics, transparency is the physical property of allowing light to pass through the material without appreciable scattering of light. On a macroscopic scale, the photons can be said to follow Snell's law. Translucency allows light to pass through but does not necessarily follow Snell's law; the photons can be scattered at either of the two interfaces, or internally, where there is a change in the index of refraction. In other words, a translucent material is made up of components with different indices of refraction. A transparent material is made up of components with a uniform index of refraction. Transparent materials appear clear, with the overall appearance of one color, or any combination leading up to a brilliant spectrum of every color. The opposite property of translucency is opacity. Other categories of visual appearance, related to the perception of regular or diffuse reflection and transmission of light, have been organized under the concept of cesia in an order system with three variables, including transparency, translucency and opacity among the involved aspects.

<span class="mw-page-title-main">Gradient-index optics</span>

Gradient-index (GRIN) optics is the branch of optics covering optical effects produced by a gradient of the refractive index of a material. Such gradual variation can be used to produce lenses with flat surfaces, or lenses that do not have the aberrations typical of traditional spherical lenses. Gradient-index lenses may have a refraction gradient that is spherical, axial, or radial.

<span class="mw-page-title-main">Photonic-crystal fiber</span> Class of optical fiber based on the properties of photonic crystals

Photonic-crystal fiber (PCF) is a class of optical fiber based on the properties of photonic crystals. It was first explored in 1996 at University of Bath, UK. Because of its ability to confine light in hollow cores or with confinement characteristics not possible in conventional optical fiber, PCF is now finding applications in fiber-optic communications, fiber lasers, nonlinear devices, high-power transmission, highly sensitive gas sensors, and other areas. More specific categories of PCF include photonic-bandgap fiber, holey fiber, hole-assisted fiber, and Bragg fiber. Photonic crystal fibers may be considered a subgroup of a more general class of microstructured optical fibers, where light is guided by structural modifications, and not only by refractive index differences. Hollow-core fibers (HCFs) are a related type of optical fiber which bears some resemblance to holey optical fiber, but may or may not be photonic depending on the fiber.

In optics, an ARROW is a type of waveguide that uses the principle of thin-film interference to guide light with low loss. It is formed from an anti-resonant Fabry–Pérot reflector. The optical mode is leaky, but relatively low-loss propagation can be achieved by making the Fabry–Pérot reflector of sufficiently high quality or small size.

A fiber Bragg grating (FBG) is a type of distributed Bragg reflector constructed in a short segment of optical fiber that reflects particular wavelengths of light and transmits all others. This is achieved by creating a periodic variation in the refractive index of the fiber core, which generates a wavelength-specific dielectric mirror. Hence a fiber Bragg grating can be used as an inline optical filter to block certain wavelengths, can be used for sensing applications, or it can be used as wavelength-specific reflector.

A prism coupler is a prism designed to couple a substantial fraction of the power contained in a beam of light into a thin film to be used as a waveguide without the need for precision polishing of the edge of the film, without the need for sub-micrometer alignment precision of the beam and the edge of the film, and without the need for matching the numerical aperture of the beam to the film. Using a prism coupler, a beam coupled into a thin film can have a diameter hundreds of times the thickness of the film. Invention of the coupler contributed to the initiation of a field of study known as integrated optics.

<span class="mw-page-title-main">Plastic optical fiber</span> Optical fiber that is made out of polymer

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<span class="mw-page-title-main">Optical fiber</span> Light-conducting fiber

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<span class="mw-page-title-main">Double-clad fiber</span>

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Thin-film interference is a natural phenomenon in which light waves reflected by the upper and lower boundaries of a thin film interfere with one another, increasing reflection at some wavelengths and decreasing it at others. When white light is incident on a thin film, this effect produces colorful reflections.

References

This article incorporates public domain material from Federal Standard 1037C. General Services Administration. Archived from the original on January 22, 2022. (in support of MIL-STD-188).

↑ "Optical Fibers". labman.phys.utk.edu. Retrieved May 26, 2023.
1 2 Zlatanov, Nikola (March 2017). "Introduction to Fiber Optics Theory". doi:10.13140/RG.2.2.29183.20641.
↑ "Fiber 101" (PDF). iBwave Solutions. Archived (PDF) from the original on November 26, 2019.
1 2 3 Hecht, Jeff (2004). City of light : the story of fiber optics. Oxford: Oxford University Press. pp. 55–70. ISBN 978-0-19-802676-1. OCLC 60543677.
1 2 Crisp, John (2005). Introduction to fiber optics. Barry J. Elliott. Amsterdam: Newnes. ISBN 978-0-7506-6756-2. OCLC 162130345.
↑ Ghatak, Ajoy; Thyagarajan, K. (1998), "Introduction: The fiber optics revolution", Introduction to fiber optics, Cambridge: Cambridge University Press, pp. 1–8, doi:10.1017/cbo9781139174770.002, ISBN 9781139174770 , retrieved November 27, 2021
1 2 "The FOA Reference For Fiber Optics - Optical Fiber". www.thefoa.org. Retrieved April 10, 2016.
↑ Bass, Michael (2010). Handbook of optics. McGraw-Hill. ISBN 978-0-07-163314-7. OCLC 904221758.

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[1] "Optical Fibers". labman.phys.utk.edu. Retrieved May 26, 2023.

[:1-2] 1 2 Zlatanov, Nikola (March 2017). "Introduction to Fiber Optics Theory". doi:10.13140/RG.2.2.29183.20641.

[3] "Fiber 101" (PDF). iBwave Solutions. Archived (PDF) from the original on November 26, 2019.

[:02-4] 1 2 3 Hecht, Jeff (2004). City of light : the story of fiber optics. Oxford: Oxford University Press. pp. 55–70. ISBN 978-0-19-802676-1. OCLC 60543677.

[:2-5] 1 2 Crisp, John (2005). Introduction to fiber optics. Barry J. Elliott. Amsterdam: Newnes. ISBN 978-0-7506-6756-2. OCLC 162130345.

[6] Ghatak, Ajoy; Thyagarajan, K. (1998), "Introduction: The fiber optics revolution", Introduction to fiber optics, Cambridge: Cambridge University Press, pp. 1–8, doi:10.1017/cbo9781139174770.002, ISBN 9781139174770 , retrieved November 27, 2021

[:3-7] 1 2 "The FOA Reference For Fiber Optics - Optical Fiber". www.thefoa.org. Retrieved April 10, 2016.

[8] Bass, Michael (2010). Handbook of optics. McGraw-Hill. ISBN 978-0-07-163314-7. OCLC 904221758.

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