The Sellmeier equation is an empirical relationship between refractive index and wavelength for a particular transparent medium. The equation is used to determine the dispersion of light in the medium.
It was first proposed in 1872 by Wolfgang Sellmeier and was a development of the work of Augustin Cauchy on Cauchy's equation for modelling dispersion.[1]
In its original and the most general form, the Sellmeier equation is given as
n2(λ)=1+\sumi
| Biλ2 | |
| λ2-Ci |
Each term of the sum representing an absorption resonance of strength Bi at a wavelength . For example, the coefficients for BK7 below correspond to two absorption resonances in the ultraviolet, and one in the mid-infrared region. Analytically, this process is based on approximating the underlying optical resonances as dirac delta functions, followed by the application of the Kramers-Kronig relations. This results in real and imaginary parts of the refractive index which are physically sensible.[2] However, close to each absorption peak, the equation gives non-physical values of n2 = ±∞, 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
\begin{matrix} n ≈ \sqrt{1+\sumiBi} ≈ \sqrt{\varepsilonr} \end{matrix},
For characterization of glasses the equation consisting of three terms is commonly used:[3] [4]
n2(λ)=1 +
| B1λ2 | |
| λ2-C1 |
+
| B2λ2 | |
| λ2-C2 |
+
| B3λ2 | |
| λ2-C3 |
,
As an example, the coefficients for a common borosilicate crown glass known as BK7 are shown below:
| Coefficient | Value | |
|---|---|---|
| B1 | 1.03961212 | |
| B2 | 0.231792344 | |
| B3 | 1.01046945 | |
| C1 | 6.00069867×10-3 μm2 | |
| C2 | 2.00179144×10-2 μm2 | |
| C3 | 1.03560653×102 μm2 |
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[5] of 365 nm to 2.3 μm, which is of the order of the homogeneity of a glass sample.[6] Additional terms are sometimes added to make the calculation even more precise.
Sometimes the Sellmeier equation is used in two-term form:[7]
n2(λ)=A+
| |||||||
| λ2-C1 |
+
| B2λ2 | |
| λ2-C2 |
.
Analytically, the Sellmeier equation models the refractive index as due to a series of optical resonances within the bulk material. Its derivation from the Kramers-Kronig relations requires a few assumptions about the material, from which any deviations will affect the model's accuracy:
{\chii}
From the last point, the complex refractive index (and the electric susceptibility) becomes:
\chii(\omega)=\sumiAi\delta(\omega-\omegai)
The real part of the refractive index comes from applying the Kramers-Kronig relations to the imaginary part:
n2=1+\chir(\omega)=1+
| 2 | |
| \pi |
| infty | |
| \int | |
| 0 |
| \omega\chii(\omega) | |
| \omega2-\Omega2 |
d\omega
Plugging in the first equation above for the imaginary component:
n2=1+
| 2 | |
| \pi |
| infty | |
| \int | |
| 0 |
\sumiAi\delta(\omega-\omegai)
| \omega | |
| \omega2-\Omega2 |
d\omega
The order of summation and integration can be swapped. When evaluated, this gives the following, where
H
n2=1+
| 2 | |
| \pi |
\sumiAi
| infty | |
| \int | |
| 0 |
\delta(\omega-\omegai)
| \omega | |
| \omega2-\Omega2 |
d\omega=1+
| 2 | |
| \pi |
\sumiAi
| \omegaiH(\omegai) | |||||||||
|
Since the domain is assumed to be far from any resonances (assumption 2 above),
H(\omegai)
n2=1+
| 2 | |
| \pi |
\sumiAi
| \omegai | |||||||||
|
By rearranging terms, the constants
Bi
Ci
| Material | B1 | B2 | B3 | C1, μm2 | C2, μm2 | C3, μm2 | |
|---|---|---|---|---|---|---|---|
| borosilicate crown glass (known as BK7) | 1.03961212 | 0.231792344 | 1.01046945 | 6.00069867×10-3 | 2.00179144×10-2 | 103.560653 | |
| sapphire (for ordinary wave) | 1.43134930 | 0.65054713 | 5.3414021 | 5.2799261×10-3 | 1.42382647×10-2 | 325.017834 | |
| sapphire (for extraordinary wave) | 1.5039759 | 0.55069141 | 6.5927379 | 5.48041129×10-3 | 1.47994281×10-2 | 402.89514 | |
| fused silica | 0.696166300 | 0.407942600 | 0.897479400 | 4.67914826×10-3 | 1.35120631×10-2 | 97.9340025 | |
| Magnesium fluoride | 0.48755108 | 0.39875031 | 2.3120353 | 0.001882178 | 0.008951888 | 566.13559 |