Miller's rule (optics)

In optics, Miller's rule is an empirical rule which gives an estimate of the order of magnitude of the nonlinear coefficient.^[1]

More formally, it states that the coefficient of the second order electric susceptibility response (${\displaystyle {\chi }_{\text{2}}}$) is proportional to the product of the first-order susceptibilities (${\displaystyle {\chi }_{\text{1}}}$) at the three frequencies which ${\displaystyle {\chi }_{\text{2}}}$ is dependent upon.^[2] The proportionality coefficient is known as Miller's coefficient ${\displaystyle \delta }$.

The first order susceptibility response is given by: $${\displaystyle {\chi }_1(\omega )=\frac{N{q}^2}{m{\epsilon }_0}\frac{1}{{\omega }_0^2-{\omega }^2-\frac{i\omega }{\tau }}}$$

where:

• ${\displaystyle \omega }$ is the frequency of oscillation of the electric field;
• ${\displaystyle {\chi }_1}$ is the first order electric susceptibility, as a function of ${\displaystyle \omega }$;
• N is the number density of oscillating charge carriers (electrons);
• q is the fundamental charge;
• m is the mass of the oscillating charges, the electron mass;
• ${\displaystyle {\epsilon }_0}$ is the electric permittivity of free space;
• i is the imaginary unit;
• ${\displaystyle \tau }$ is the free carrier relaxation time;

For simplicity, we can define ${\displaystyle D(\omega )}$, and hence rewrite ${\displaystyle {\chi }_1}$: $${\displaystyle D(\omega )={\omega }_0^2-{\omega }^2-\frac{i\omega }{\tau }}$$ $${\displaystyle {\chi }_1(\omega )=\frac{N{q}^2}{{\epsilon }_{0}m}\frac{1}{D(\omega )}}$$

The second order susceptibility response is given by: $${\displaystyle {\chi }_2(2\omega )=\frac{N{q}^3{\zeta }_2}{{\epsilon }_0{m}^2}\frac{1}{D(2\omega )D(\omega {)}^2}}$$ where ${\displaystyle {\zeta }_2}$ is the first anharmonicity coefficient. It is easy to show that we can thus express ${\displaystyle {\chi }_2}$ in terms of a product of ${\displaystyle {\chi }_1}$ $${\displaystyle {\chi }_2(2\omega )=\frac{{\epsilon }_0^{2}m{\zeta }_2}{N^2{q}^3}{\chi }_1(\omega ){\chi }_1(\omega ){\chi }_1(2\omega )}$$

The constant of proportionality between ${\displaystyle {\chi }_2}$ and the product of ${\displaystyle {\chi }_1}$ at three different frequencies is Miller's coefficient: $${\displaystyle \delta =\frac{{\epsilon }_0^{2}m{\zeta }_2}{N^2{q}^3}}$$

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