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In optics, 'dispersion' is a phenomenon that causes the separation of a wave into spectral components which have different wavelengths, due to a dependence of the wave's speed on its wavelength. It is most often described in light waves, but it may happen to any kind of wave that interacts with a medium or can be confined to a waveguide, such as sound waves. Dispersion is sometimes called '''chromatic'' dispersion' to emphasize its wavelength-dependent nature.
There are generally two sources of dispersion: 'material dispersion' and 'waveguide dispersion'. Material dispersion comes from a frequency-dependent response of a material to waves. For example, material dispersion leads to undesired chromatic aberration in a lens or the separation of colors in a prism. Waveguide dispersion occurs when the speed of a wave in a waveguide (such as an optical fiber) depends on its frequency for geometric reasons, independent of any frequency dependence of the materials from which it is constructed. This type of dispersion leads to signal degradation in telecommunications because the varying delay in arrival time between different components of a signal "smears out" the signal in time.

Contents

Material dispersion in optics

Group and phase velocity

Dispersion in waveguides

Dispersion in gemology

Dispersion in imaging

See also

External links

Material dispersion in optics

Material dispersion can be a desirable or undesirable effect in optical applications. The dispersion of light by glass prisms is used to construct spectrometers and spectroradiometers. Holographic gratings are also used, as they allow more accurate discrimination of wavelengths. However, in lenses, dispersion causes chromatic aberration, an undesired effect that may distort images in microscopes, telescopes and photographic objectives.
The ''phase velocity'' of a wave ''v'' in a given uniform medium is given by
:
where ''c'' is the speed of light in a vacuum and ''n'' is the refractive index of the medium.
In general, the refractive index is some function of the frequency f of the light, thus ''n'' = ''n''(f), or alternately, with respect to the wave's wavelength ''n'' = ''n''(λ). The wavelength dependency of a material's refractive index is usually quantified by an empirical formula, the Cauchy or Sellmeier equations.
The most commonly seen consequence of dispersion in optics is the separation of white light into a color spectrum by a prism. From Snell's law it can be seen that the angle of refraction of light in a prism depends on the refractive index of the prism material. Since that refractive index varies with wavelength, it follows that the angle that the light is refracted will also vary with wavelength, causing an angular separation of the colors known as ''angular dispersion''.
For visible light, most transparent materials (e.g. glasses) have:
:
m red}) < n(lambda_{
m yellow}) < n(lambda_{
m blue}) ,
or alternatively:
:
m d}n}{{
m d}lambda} < 0,
that is, refractive index ''n'' decreases with increasing wavelength λ. In this case, the medium is said to have ''normal dispersion''. Whereas, if the index increases with increasing wavelength the medium has ''anomalous dispersion''.
At the interface of such a material with air or vacuum (index of ~1), Snell's law predicts that light incident at an angle θ to the normal will be refracted at an angle arcsin( sin (θ) / ''n'') . Thus, blue light, with a higher refractive index, will be bent more strongly than red light, resulting in the well-known rainbow pattern.

Group and phase velocity

Another consequence of dispersion manifests itself as a temporal effect. The formula above, ''v'' = ''c'' / ''n'' calculates the ''phase velocity'' of a wave; this is the velocity at which the ''phase'' of any one frequency component of the wave will propagate. This is not the same as the ''group velocity'' of the wave, which is the rate that changes in amplitude (known as the ''envelope'' of the wave) will propagate. The group velocity ''v''_g is related to the phase velocity by, for a homogeneous medium (here $lambda$ is the wavelength in vacuum, not in the medium):
:
ight]^{-1}.
The group velocity ''v''_g is often thought of as the velocity at which energy or information is conveyed along the wave. In most cases this is true, and the group velocity can be thought of as the ''signal velocity'' of the waveform. In some unusual circumstances, where the wavelength of the light is close to an absorption resonance of the medium, it is possible for the group velocity to exceed the speed of light (''v''_g > ''c''), leading to the conclusion that superluminal (faster than light) communication is possible. In practice, in such situations the distortion and absorption of the wave is such that the value of the group velocity essentially becomes meaningless, and does not represent the true signal velocity of the wave, which stays less than ''c''.
The group velocity itself is usually a function of the wave's frequency. This results in 'group velocity dispersion' (GVD), which causes a short pulse of light to spread in time as a result of different frequency components of the pulse travelling at different velocities. GVD is often quantified as the ''group delay dispersion parameter'' (again, this formula is for a uniform medium only):
:
ight).
If ''D'' is less than zero, the medium is said to have ''positive dispersion''. If ''D'' is greater than zero, the medium has ''negative dispersion''.If a light pulse is propagated through a normally dispersive medium, the result is the higher frequency components travel slower than the lower frequency components. The pulse therefore becomes ''positively chirped'', or ''up-chirped'', increasing in frequency with time. Conversely, if a pulse travels through an anomalously dispersive medium, high frequency components travel faster than the lower ones, and the pulse becomes ''negatively chirped'', or ''down-chirped'', decreasing in frequency with time.
The result of GVD, whether negative or positive, is ultimately temporal spreading of the pulse. This makes dispersion management extremely important in optical communications systems based on optical fiber, since if dispersion is too high, a group of pulses representing a bit-stream will spread in time and merge together, rendering the bit-stream unintelligible. This limits the length of fiber that a signal can be sent down without regeneration. One possible answer to this problem is to send signals down the optical fibre at a wavelength where the GVD is zero (e.g. around ~1.3-1.5 μm in silica fibres), so pulses at this wavelength suffer minimal spreading from dispersion—in practice, however, this approach causes more problems than it solves because zero GVD unacceptably amplifies other nonlinear effects (such as four wave mixing). Another possible option is to use soliton pulses in the regime of anomalous dispersion, a form of optical pulse which uses a nonlinear optical effect to self-maintain its shape—solitons have the practical problem, however, that they require a certain power level to be maintained in the pulse for the nonlinear effect to be of the correct strength. Instead, the solution that is currently used in practice is to perform dispersion compensation, typically by matching the fiber with another fiber of opposite-sign dispersion so that the dispersion effects cancel; such compensation is ultimately limited by nonlinear effects such as self-phase modulation, which interact with dispersion to make it very difficult to undo.
Dispersion control is also important in lasers that produce short pulses. The overall dispersion of the optical resonator is a major factor in determining the duration of the pulses emitted by the laser. A pair of prisms can be arranged to produce net negative dispersion, which can be used to balance the usually positive dispersion of the laser medium. Diffraction gratings can also be used to produce dispersive effects; these are often used in high-power laser amplifier systems. Recently, an alternative to prisms and gratings has been developed: chirped mirrors. These dielectric mirrors are coated so that different wavelengths have different penetration lengths, and therefore different group delays. The coating layers can be tailored to achieve a net negative dispersion.

Dispersion in waveguides

Optical fibers, which are used in telecommunications, are among the most abundant types of waveguides. Dispersion in these fibers are one of the limiting factors that determine how much data can be transported on a single fiber.
The transverse modes for waves confined laterally within a waveguide generally have different speeds (and field patterns) depending upon their frequency (that is, on the relative size of the wave, the wavelength) compared to the size of the waveguide.
A similar phenomenon is modal dispersion, caused by a waveguide having multiple modes at a given frequency, each with a different speed. A special case of this is polarization mode dispersion (PMD), which comes from a superposition of two modes that travel at different speeds due to random imperfections that break the symmetry of the waveguide.

Dispersion in gemology

In the technical terminology of gemology, ''dispersion'' is the difference in the refractive index of a material at the B and G Fraunhofer wavelengths of 686.7 nm and 430.8 nm and is meant to express the degree to which a prism cut from the gemstone shows "fire", or color. Dispersion is a material property. Fire depends on the dispersion, the cut angles, the lighting environment, the refractive index, and the viewer.

Dispersion in imaging

In photographic and microscopic lenses, dispersion causes chromatic aberration, distorting the image, and various techniques have been developed to counteract it.

See also

★ Abbe number

★ Group delay

★ Dispersion relation

External links

★ Optical Characteristics of the SF10 Crystal Prism

★ Deviation Angle for a Prism

★ Dispersive Wiki - discussing the mathematical aspects of dispersion.

★ Dispersion - Encyclopedia of Laser Physics and Technology