Sellmeier equation
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In optics, the Sellmeier equation is an empirical relationship between refractive index n and wavelength λ for a particular transparent medium. The usual form of the equation for glasses[1] is
where B1,2,3 and C1,2,3 are experimentally determined Sellmeier coefficients. These coefficients are usually quoted for λ in micrometres. Note that this λ is the vacuum wavelength; not that in the material itself, which is λ/n(λ).
The equation is used to determine the dispersion of light in a refracting medium. A different form of the equation is sometimes used for certain types of materials, e.g. crystals.
The equation was deduced in 1871 by W. Sellmeier, and was a development of the work of Augustin Cauchy on Cauchy's equation for modelling dispersion.
As an example, the coefficients for a common borosilicate crown glass known as BK7 are shown below:
Coefficient | Value |
---|---|
B1 | 1.03961212 |
B2 | 2.31792344x10−1 |
B3 | 1.01046945 |
C1 | 6.00069867x10−3 μm2 |
C2 | 2.00179144x10−2 μm2 |
C3 | 1.03560653x102 μm2 |
The Sellmeier coefficients for many common optical glasses can be found in the Schott Glass catalogue, or in the Ohara catalogue.
For common optical glasses, the refractive index calculated with the three-term Sellmeier equation deviates from the actual refractive index by less than 5×10-6 over the wavelengths range of 365 nm to 2.3 µm[1], which is of the order of the homogeneity of a glass sample [2]. Additional terms are sometimes added to make the calculation even more precise. In its most general form, the Sellmeier equation is given as
with each term of the sum representing an absorption resonance of strength Bi at a wavelength √Ci. For example, the coefficients for BK7 above correspond to two absorption resonances in the ultraviolet, and one in the mid-infrared region. Close to each absorption peak, the equation gives non-physical values of n=±∞, and in these wavelength regions a more precise model of dispersion such as Helmholtz's must be used.
If all terms are specified for a material, at long wavelengths far from the absorption peaks the value of n tends to
where εr is the relative dielectric constant of the medium.
The Sellmeier equation can also be given in another form:
Here the coefficient A is an approximation of the short-wavelength (e.g., ultraviolet) absorption contributions to the refractive index at longer wavelengths. Other variants of the Sellmeier equation exist that can account for a material's refractive index change due to temperature, pressure, and other parameters.
Contents |
[edit] Coefficients
Table of coefficients of Sellmeier equation[3] | ||||||
---|---|---|---|---|---|---|
Material | B1 | B2 | B3 | C1 | C2 | C3 |
borosilicate crown glass (known as BK7) |
1.03961212 | 2.31792344x10−1 | 1.01046945 | 6.00069867x10−3µm2 | 2.00179144x10−2µm2 | 1.03560653x102µm2 |
sapphire (for ordinary wave) |
1.43134930 | 6.5054713x10−1 | 5.3414021 | 5.2799261x10−3µm2 | 1.42382647x10−2µm2 | 3.25017834x102µm2 |
sapphire (for extraordinary wave) |
1.5039759 | 5.5069141x10−1 | 6.5937379 | 5.48041129x10−3µm2 | 1.47994281x10−2µm2 | 4.0289514x102µm2 |
[edit] See also
[edit] References
- ^ Refractive index and dispersion. Schott technical information document TIE-29 (2005).
- W. Sellmeier, Annalen der Physik und Chemie 143, 271 (1871)
[edit] External links
- A PDF giving Sellmeier coefficients for several common glasses and optical materials
- An XLS file with dispersion coefficients and other optical properties of all Schott glasses.
- A browser-based calculator giving refractive index from Sellmeier coefficients.
- Annalen der Physik - free Access, ditizied by the french national library