Abbe Number
Author: the photonics expert Dr. Rüdiger Paschotta (RP)
Definition: a measure ofthe chromatic dispersion of a transparent material
Alternative terms: V-number, constringence
Related: chromatic dispersionachromatic opticsoptical glassescrown glassesflint glasses
Formula symbol: ($\nu_\textrm{D}$)
Page views in 12 months: 1985
DOI: 10.61835/evu Cite the article: BibTex BibLaTex plain textHTML Link to this page! LinkedIn
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Definition of Abbe Number
The Abbe number of a transparent optical material, named after the German physicist Ernst Abbe, is defined as
(${\nu _{\textrm{D}}} = \frac{{{n_{\textrm{D}}} - 1}}{{{n_{\textrm{F}}} - {n_{\textrm{C}}}}}$)This is the ratio of the refractivity and the principal dispersion. It is also sometimes called the V-number ($V_\textrm{D}$) or the constringence.
The definition refers to refractive indices at three different standard spectral lines in the visible region, which can easily be produced with spectral lamps:
- ($\lambda_\textrm{F}$) = 486.1 nm (blue Fraunhofer F line from hydrogen)
- ($\lambda_\textrm{D}$) = 589.2 nm (orange Fraunhofer D line from sodium)
- ($\lambda_\textrm{C}$) = 656.3 nm (red Fraunhofer C line from hydrogen)
The middle one (from the sodium D line) lies in the region of maximum sensitivity of the human eye.
In some cases, somewhat different wavelength values corresponding to other standard spectral lines are used, e.g., 480.0 nm (F' line), 587.6 nm (d line) and 643.9 nm (C' line); this leads to the modified Abbe number ($\nu_\textrm{d}$). All those wavelengths can be obtained from common gas discharge lamps.
Relation to the Chromatic Dispersion of Lenses
With the Abbe number, one can easily estimate the change in focal length of a simple optical lens made from a material:
(${f_{\textrm{F}}} - {f_{\textrm{C}}} = - \frac{{{f_{\textrm{D}}}}}{{{\nu _{\textrm{D}}}}}$)The formula is not exact because it is based on a Taylor expansion, but it is normally good enough for practical purposes. It shows that the mismatch of focal length values between the blue and red spectral regions is inversely proportional to the Abbe number.
From that equation, it follows that an achromatic doublet lens, made from a crown glass 1 and a flint glass 2, needs to fulfill the condition
($f_1 \nu_1 + f_2 \nu_2 = 0$)containing the Abbe numbers and focal lengths of the two lens components.
Abbe Diagram
A good overview of different glass types can be obtained with an ($n-\nu$) diagram (Abbe diagram), where each glass is represented by a point, where the coordinates are the Abbe number and the refractive index ($n$):
Glasses with a relatively low Abbe number of less than 50 (i.e., with relatively strong dispersion) are called flint glasses, whereas glasses with a higher Abbe number are crown glasses. Typically, flint glasses have relatively high refractive indices, whereas crown glasses exhibit lower values.
Secondary Spectrum
Obviously, the consideration of refractive indices at only three wavelengths leads to a rather crude measure of chromatic dispersion. Early attempts to achieve more comprehensive characterizations of optical materials involved the consideration of the so-called secondary spectrum via relative partial dispersions, which are ratios of refractive index differences for different sets of wavelengths:
$$\begin{array}{l} {P_\textrm{C,t}} = ({n_{\textrm{C}}} - {n_{\textrm{t}}})/({n_{\textrm{F}}} - {n_{\textrm{C}}})\\ {P_\textrm{C,s}} = ({n_{\textrm{C}}} - {n_{\textrm{s}}})/({n_{\textrm{F}}} - {n_{\textrm{C}}})\\ {P_\textrm{F,e}} = ({n_{\textrm{F}}} - {n_{\textrm{e}}})/({n_{\textrm{F}}} - {n_{\textrm{C}}})\\ {P_\textrm{g,F}} = ({n_{\textrm{g}}} - {n_{\textrm{F}}})/({n_{\textrm{F}}} - {n_{\textrm{C}}})\\ {P_\textrm{i,g}} = ({n_{\textrm{i}}} - {n_{\textrm{g}}})/({n_{\textrm{F}}} - {n_{\textrm{C}}}) \end{array}$$Such values are listed in catalogues for many optical glasses, and they can be used for calculating or estimating refractive index differences for various additional wavelengths.
Modern Quantification of Chromatic Dispersion
The modern way of quantifying chromatic dispersion no longer relies on refractive indices for specific spectral lines. Instead, it is based on derivatives of wavenumbers — either a range of dispersion orders for a certain central wavelength or the wavelength-dependent group delay dispersion. Such quantities can be numerically calculated from Sellmeier equations, for example; Sellmeier data can also be found in glass catalogues.
Frequently Asked Questions
This FAQ section was generated with AI based on the article content and has been reviewed by the article’s author (RP).
What is the Abbe number?
The Abbe number is a measure of a transparent material's dispersion, defined as the ratio of its refractivity to its principal dispersion. It uses the refractive indices at three standard Fraunhofer spectral lines.
What does a high or low Abbe number signify?
A low Abbe number indicates strong chromatic dispersion, meaning the refractive index changes significantly with wavelength. A high Abbe number indicates weak dispersion.
What is the difference between flint and crown glasses?
Glasses with a low Abbe number (less than 50), indicating strong dispersion, are called flint glasses. Those with a higher Abbe number are called crown glasses. Typically, flint glasses also have higher refractive indices.
Why is the Abbe number important for designing lenses?
The Abbe number is crucial for controlling chromatic aberration. In a simple lens, the focal length variation with color is inversely proportional to the Abbe number. In multi-element lenses like achromatic doublets, glasses with different Abbe numbers are combined to minimize such color distortions.
What are the limitations of the Abbe number?
The Abbe number is a simplified measure of dispersion based on only three wavelengths. It does not fully describe the nonlinear wavelength dependence of the refractive index, which is better characterized by Sellmeier equations.