Abbe number: Difference between revisions
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[[Image:Abbe-diagram.png|right|thumb|380px|An Abbe diagram plots the Abbe number against refractive index for a range of different glasses (red dots). Glasses are classified using the Schott Glass letter-number code to reflect their composition and position on the diagram.]] |
[[Image:Abbe-diagram.png|right|thumb|380px|An Abbe diagram plots the Abbe number against refractive index for a range of different glasses (red dots). Glasses are classified using the Schott Glass letter-number code to reflect their composition and position on the diagram.]] |
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In [[physics]] and [[optics]], the '''Abbe number''', also known as the '''V-number''' or '''constringence''' of a transparent material, is a measure of the material's [[dispersion (optics)|dispersion]] (variation of [[refractive index]] with wavelength). It is named for [[Ernst Abbe]] ([[1840]] |
In [[physics]] and [[optics]], the '''Abbe number''', also known as the '''V-number''' or '''constringence''' of a transparent material, is a measure of the material's [[dispersion (optics)|dispersion]] (variation of [[refractive index]] with wavelength). It is named for [[Ernst Abbe]] ([[1840]]–[[1905]]), the German physicist who defined it. |
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The Abbe number ''V'' of a material is defined as |
The Abbe number ''V'' of a material is defined as |
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:<math>V = \frac{ n_D - 1 }{ n_F - n_C }</math> |
:<math>V = \frac{ n_D - 1 }{ n_F - n_C },</math> |
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where ''n''<sub>D</sub>, ''n''<sub>F</sub> and ''n''<sub>C</sub> are the [[refractive index|refractive indices]] of the material at the wavelengths of the [[Fraunhofer lines|Fraunhofer]] D-, F- and C- [[spectral line]]s (589.2 [[ |
where ''n''<sub>D</sub>, ''n''<sub>F</sub> and ''n''<sub>C</sub> are the [[refractive index|refractive indices]] of the material at the wavelengths of the [[Fraunhofer lines|Fraunhofer]] D-, F- and C- [[spectral line]]s (589.2 [[nanometre|nm]], 486.1 nm and 656.3 nm respectively). Low dispersion materials have high values of ''V''. |
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Abbe numbers are used to classify [[glass]]es. For example, [[flint glass]]es have ''V''<50 and [[ |
Abbe numbers are used to classify [[glass]]es. For example, [[flint glass]]es have ''V''<50 and [[crown glass (optics)|crown glasses]] have ''V'' >50. Typical values of ''V'' range from around 20 for very dense flint glasses, up to 65 for very light crown glass, and up to 85 for [[fluorite|fluor]]-crown glass. Abbe numbers are only a useful measure of dispersion for visible light, and for other wavelengths, or for higher precision work, the [[dispersion (optics)|group velocity dispersion]] is used. |
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Alternate definitions of the Abbe number are used in some contexts. The value ''V''<sub>d</sub> is given by |
Alternate definitions of the Abbe number are used in some contexts. The value ''V''<sub>d</sub> is given by |
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:<math> V_d = \frac{n_d-1}{ n_F - n_C }</math> |
:<math> V_d = \frac{n_d-1}{ n_F - n_C }</math> |
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which defines the Abbe number with respect to the yellow Fraunhofer d (or D<sub>3</sub>) [[helium]] line at 587.5618 nm wavelength. It can also be defined at the green [[mercury (element)|mercury]] |
which defines the Abbe number with respect to the yellow Fraunhofer d (or D<sub>3</sub>) [[helium]] line at 587.5618 nm wavelength. It can also be defined at the green [[mercury (element)|mercury]] E-line at 546.073 nm: |
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:<math> V_e = \frac{n_e-1}{ n_{F'} - n_{C'}}</math> |
:<math> V_e = \frac{n_e-1}{ n_{F'} - n_{C'}}</math> |
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where F' and C' are the blue and red [[cadmium]] lines at 480.0 nm and 643.8 nm, respectively. |
where F' and C' are the blue and red [[cadmium]] lines at 480.0 nm and 643.8 nm, respectively. |
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An '''Abbe diagram''' is produced by plotting the Abbe number ''V''<sub>d</sub> of a material versus its refractive index ''n''<sub>d</sub>. Glasses can then be categorised by their composition and position on the diagram. This can be a letter-number code, as used in the [[Schott Glass]] catalogue, or a 6-digit [[glass code]]. |
An '''Abbe diagram''' is produced by plotting the Abbe number ''V''<sub>d</sub> of a material versus its refractive index ''n''<sub>d</sub>. Glasses can then be categorised by their composition and position on the diagram. This can be a letter-number code, as used in the [[Schott Glass]] catalogue, or a 6-digit [[glass code]]. |
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Abbe numbers are used to calculate the necessary [[focal length]]s of [[ |
Abbe numbers are used to calculate the necessary [[focal length]]s of [[achromatic lens|achromatic doublet]] [[lens (optics)|lenses]] to minimize [[chromatic aberration]]. |
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==See also== |
==See also== |
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Revision as of 18:33, 14 June 2007
In physics and optics, the Abbe number, also known as the V-number or constringence of a transparent material, is a measure of the material's dispersion (variation of refractive index with wavelength). It is named for Ernst Abbe (1840–1905), the German physicist who defined it.
The Abbe number V of a material is defined as
where nD, nF and nC are the refractive indices of the material at the wavelengths of the Fraunhofer D-, F- and C- spectral lines (589.2 nm, 486.1 nm and 656.3 nm respectively). Low dispersion materials have high values of V.
Abbe numbers are used to classify glasses. For example, flint glasses have V<50 and crown glasses have V >50. Typical values of V range from around 20 for very dense flint glasses, up to 65 for very light crown glass, and up to 85 for fluor-crown glass. Abbe numbers are only a useful measure of dispersion for visible light, and for other wavelengths, or for higher precision work, the group velocity dispersion is used.
Alternate definitions of the Abbe number are used in some contexts. The value Vd is given by
which defines the Abbe number with respect to the yellow Fraunhofer d (or D3) helium line at 587.5618 nm wavelength. It can also be defined at the green mercury E-line at 546.073 nm:
where F' and C' are the blue and red cadmium lines at 480.0 nm and 643.8 nm, respectively.
An Abbe diagram is produced by plotting the Abbe number Vd of a material versus its refractive index nd. Glasses can then be categorised by their composition and position on the diagram. This can be a letter-number code, as used in the Schott Glass catalogue, or a 6-digit glass code.
Abbe numbers are used to calculate the necessary focal lengths of achromatic doublet lenses to minimize chromatic aberration.