Condon model

In optics and materials science, Condon model is a mathematical formula for the frequency dependence of the chirality parameter of bi-isotropic or bi-anisotropic media. It was reported by Edward Condon, William Altar and Henry Eyring in 1937 in its definitive form,^[1][2] with its earlier forms being introduced by Max Born, Heinrich Gerhard Kuhn and Léon Rosenfeld, among others.^[3]

Electric and magnetic constitutive relations for a dispersive and reciprocal chiral material are written as:^[4]

${\displaystyle \mathbf{\text{𝐃}}=\epsilon (\omega )\mathbf{\text{𝐄}}-i\kappa (\omega )\sqrt{\epsilon (\omega )\mu (\omega )}\mathbf{\text{𝐇}}}$

${\displaystyle \mathbf{\text{𝐁}}=\mu (\omega )\mathbf{\text{𝐇}}+i\kappa (\omega )\sqrt{\epsilon (\omega )\mu (\omega )}\mathbf{\text{𝐄}}}$

where $\epsilon (\omega )$ and $\mu (\omega )$ are the frequency-dependent permittivity and magnetic susceptibility. $\kappa (\omega )$ denotes the chirality parameter for magnetoelectric coupling. Using a quantum mechanical treatment of molecular transitions that facilitate chiral behavior, Condon et al. arrives at a single oscillator oscillator expression for the chirality parameter, known as "the one‐electron rotatory power":^[1][2][4]

${\displaystyle \kappa (\omega )=\frac{\omega R}{{\omega }^2-{\omega }^2-i\omega \Gamma }}$

where

• ${\omega }_0$ is the angular resonant frequency of the molecular transition.
• $\Gamma$ is the damping term.
• $R$ is the rotational strength of the molecular transition.

Alternatively, an expression with multiple oscillators can be used to denote multiple molecular transition between the states$a$ to $b$:^[5]

${\displaystyle \kappa (\omega )=\sum _b\frac{\omega R_{ba}}{{\omega }_{0,ba}^2-{\omega }^2-i\omega {\Gamma }_{ba}}}$

Under passivity constraints, imaginary parts of the complex Condon expression and the other constitutive paremeters obey the inequality:^[4]

${\displaystyle \text{Im}{[\kappa (\omega )]}^2<\text{Im}[\epsilon (\omega )]\text{Im}[\mu (\omega )]c_0^2}$

where $c_0$ is the speed of light in vacuum. The model is often approximated with a single-pole oscillator whose resonance lies far away from other molecular transitions. The presence of angular frequency ($\omega$) term in the numerator suggests the absence of chirality in the static limit.^[4] Since the model is causal and thus obeys the Kramers–Kronig relations,^[6] it is used in the time-domain analytical and numerical modeling of wave propagation in chiral media.^{[7][8][9][10]}

Condon model parameters of chiral materials such as glucose solutions and metamaterials can be retrieved from experimental measurements of optical rotatory dispersion^[6] and electromagnetic simulation data.^[11]

• Franck–Condon principle
• Lorentz oscillator model