Dispersion and Scattering: Difference between revisions

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==Dispersion==
==Dispersion==


Different frequencies of light contain different phase velocities because of the material they pass through's properties.  When the velocity differs, dispersion occurs.  The most recognizable act of dispersion is seen in most transparent materials, when there is a decrease in index of refraction, which leads to an increase in wavelength.  
Different frequencies of light contain different phase velocities because of the material they pass through's properties.  When the velocity differs, dispersion occurs ("Dispersion).  


===Normal Dispersion===
===Normal Dispersion===
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===Dispersion Delay Parameter===
===Dispersion Delay Parameter===


The different kinds of dispersion cause changes in the group characteristics of the wave.  These group characteristics are the features of the wave packet that change with the same frequency as the amplitude of the wave. "Group velocity dispersion" occurs as a spreading-out of the signal "envelope" of the radiation.  This dispersion can be calculated with a group dispersion delay parameter: <math>D = {\frac{1}{{v}_{g}^2}} {\frac{d{v}_{g}}{dλ}}</math>, and we know that group velocity, <math>{v}_{g}</math>, is <math>{\frac{c}{n-λ{\frac{dn}{dλ}}}}</math>, where n is the index of refraction and c is the speed of light through a vacuum.  Combining these two equations gives us a simpler form of the dispersion delay parameter:<math>D = {\frac{-λ}{c}} {\frac{d^2n}{dλ^2}}</math>
The different kinds of dispersion cause changes in the group characteristics of the wave.  These group characteristics are the features of the wave packet that change with the same frequency as the amplitude of the wave. "Group velocity dispersion" occurs as a spreading-out of the signal "envelope" of the radiation.  This dispersion can be calculated with a group dispersion delay parameter: <math>D = {\frac{1}{{v}_{g}^2}} {\frac{d{v}_{g}}{dλ}}</math>, and we know that group velocity, <math>{v}_{g}</math>, is <math>{\frac{c}{n-λ{\frac{dn}{dλ}}}}</math>, where n is the index of refraction and c is the speed of light through a vacuum.  Combining these two equations gives us a simpler form of the dispersion delay parameter:<math>D = {\frac{-λ}{c}} {\frac{d^2n}{dλ^2}}</math>.


If D is less than zero, the medium is said to have positive dispersion or normal 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 slow down more than the lower frequency components. The pulse therefore becomes positively chirped, or up-chirped, increasing in frequency with time. This causes the spectrum coming out of a prism to appear with red light the least refracted and blue/violet light the most refracted. Conversely, if a pulse travels through an anomalously (negatively) 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.
If D is less than zero, the medium is said to have positive, or known as normal, dispersion. If a light wave is propagated through a normally dispersive medium, then the result is that the higher frequency components slow down more than the lower frequency components. Because of this, the pulse becomes positively chirped, which means that the frequency increases with time. This is the reason for the spectrum that comes out of a prism to appear with red light as the least refracted and blue/violet light as the most refracted.


 
One the other hand, if D is greater than zero, the medium has negative dispersionThis means that when a light travels through an negatively (anomalously) medium, high frequency components travel faster than the lower ones, and the pulse becomes negatively chirped, so the frequency decreases with time ("Optics).
What are the mathematical equations that allow us to model this topicFor example <math>{\frac{d\vec{p}}{dt}}_{system} = \vec{F}_{net}</math> where '''p''' is the momentum of the system and '''F''' is the net force from the surroundings.
 
===A Computational Model===
 
How do we visualize or predict using this topic. Consider embedding some vpython code here [https://trinket.io/glowscript/31d0f9ad9e Teach hands-on with GlowScript]


==Examples==
==Examples==


Be sure to show all steps in your solution and include diagrams whenever possible
Given the indices of refraction, calculate the v values for crown glass and flint glass. The refraction indices corresponding to the wavelengths of the Fraunhofer lines, F, D, and C, are 1.5293, 1.5230, and 1.5204, respectively, for crown glass.  For flint glass, the refraction indices corresponding to the wavelengths of the Fraunhofer lines, F, D, and C, are 1.7378, 1.7200, and 1.7130, respectively.  Once the v values have been calculated, explain which of the two glasses has a higher dispersion.
 
===Simple===
===Middling===
===Difficult===


==Connectedness==
<math>{v}_{crown} = {\frac{{n}_{D} - 1}{{n}_{F} - {n}_{C}}} = {\frac{1.5230 - 1}{1.5293 - 1.5204}} = 58.76</math>
#How is this topic connected to something that you are interested in?
#How is it connected to your major?
#Is there an interesting industrial application?


==History==
<math>{v}_{flint} = {\frac{{n}_{D} - 1}{{n}_{F} - {n}_{C}}} = {\frac{1.7200 - 1}{1.7378 - 1.7139}} = 29.03</math>


Put this idea in historical context. Give the reader the Who, What, When, Where, and Why.


== See also ==
Since the v value of crown class is higher, it has a lower dispersion. So the glass with the highest dispersion is flint glass.


Are there related topics or categories in this wiki resource for the curious reader to explore?  How does this topic fit into that context?


===Further reading===
===Further reading===


Books, Articles or other print media on this topic
[https://en.wikipedia.org/wiki/Optics#Dispersion_and_scattering Wiki Article on Optics]
[https://en.wikipedia.org/wiki/Abbe_number Wiki Article on Abbe Number]


===External links===
===External links===
[http://www.scientificamerican.com/article/bring-science-home-reaction-time/]
[http://hyperphysics.phy-astr.gsu.edu/hbase/geoopt/dispersion.html Dispersion on HyperPhysics]




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[[Category:Which Category did you place this in?]]
[[Category:Optics]]

Revision as of 22:56, 5 December 2015

When a wavelength changes index of refraction, there is some scattering of the wavelengths and this phenomena is called dispersion.

Dispersion

Different frequencies of light contain different phase velocities because of the material they pass through's properties. When the velocity differs, dispersion occurs ("Dispersion).

Normal Dispersion

Dispersion that occurs in wavelength ranges where the material does not absorb light is normal dispersion. When a light travels through a transparent material, there is a decrease in index of refraction, which leads to an increase in the wavelength of the light. This is an example of normal dispersion, because the material doesn't absorb the light. Another example is the separation of colors that occurs when light passes through a glass prism. When the light comes into the surface of the prism, the light incident to the normal, at a certain angle, θ, will be refracted at an angle that is equal to arcsin(sin(θ)/n), according to Snell's law. This demonstrates why there is a rainbow patter, because a blue light, for example, has a high refractive index so its wavelength would be bent more strongly than red light, because red light has a smaller refractive index.

Material Dispersion

When light has a wavelength range that results in the medium having significant absorbing, the index of refraction can increase with wavelength, and result in material dispersion. This type of dispersion is characterized by the Abbe's number: [math]\displaystyle{ {\frac{{n}_{D} - 1}{{n}_{F} - {n}_{C}}} }[/math], which gives a simple measure of dispersion based on the index of refraction at three specific wavelengths. The Abbe number is also known as the v value, a low v value implies high dispersion ("Abbe).

Dispersion Delay Parameter

The different kinds of dispersion cause changes in the group characteristics of the wave. These group characteristics are the features of the wave packet that change with the same frequency as the amplitude of the wave. "Group velocity dispersion" occurs as a spreading-out of the signal "envelope" of the radiation. This dispersion can be calculated with a group dispersion delay parameter: [math]\displaystyle{ D = {\frac{1}{{v}_{g}^2}} {\frac{d{v}_{g}}{dλ}} }[/math], and we know that group velocity, [math]\displaystyle{ {v}_{g} }[/math], is [math]\displaystyle{ {\frac{c}{n-λ{\frac{dn}{dλ}}}} }[/math], where n is the index of refraction and c is the speed of light through a vacuum. Combining these two equations gives us a simpler form of the dispersion delay parameter:[math]\displaystyle{ D = {\frac{-λ}{c}} {\frac{d^2n}{dλ^2}} }[/math].

If D is less than zero, the medium is said to have positive, or known as normal, dispersion. If a light wave is propagated through a normally dispersive medium, then the result is that the higher frequency components slow down more than the lower frequency components. Because of this, the pulse becomes positively chirped, which means that the frequency increases with time. This is the reason for the spectrum that comes out of a prism to appear with red light as the least refracted and blue/violet light as the most refracted.

One the other hand, if D is greater than zero, the medium has negative dispersion. This means that when a light travels through an negatively (anomalously) medium, high frequency components travel faster than the lower ones, and the pulse becomes negatively chirped, so the frequency decreases with time ("Optics).

Examples

Given the indices of refraction, calculate the v values for crown glass and flint glass. The refraction indices corresponding to the wavelengths of the Fraunhofer lines, F, D, and C, are 1.5293, 1.5230, and 1.5204, respectively, for crown glass. For flint glass, the refraction indices corresponding to the wavelengths of the Fraunhofer lines, F, D, and C, are 1.7378, 1.7200, and 1.7130, respectively. Once the v values have been calculated, explain which of the two glasses has a higher dispersion.

[math]\displaystyle{ {v}_{crown} = {\frac{{n}_{D} - 1}{{n}_{F} - {n}_{C}}} = {\frac{1.5230 - 1}{1.5293 - 1.5204}} = 58.76 }[/math]

[math]\displaystyle{ {v}_{flint} = {\frac{{n}_{D} - 1}{{n}_{F} - {n}_{C}}} = {\frac{1.7200 - 1}{1.7378 - 1.7139}} = 29.03 }[/math]


Since the v value of crown class is higher, it has a lower dispersion. So the glass with the highest dispersion is flint glass.


Further reading

Wiki Article on Optics Wiki Article on Abbe Number

External links

Dispersion on HyperPhysics


References

1. "Abbe Number." Wikipedia. Wikimedia Foundation. Web. 4 Dec. 2015. <https://en.wikipedia.org/wiki/Abbe_number>.

2. "Dispersion." HyperPhysics. HyperPhysics. Web. 1 Dec. 2015. <http://hyperphysics.phy-astr.gsu.edu/hbase/geoopt/dispersion.html>.

3. "Optics." Wikipedia. Wikimedia Foundation, 2015. Web. 2 Dec. 2015. <https://en.wikipedia.org/wiki/Optics#Dispersion_and_scattering>.