Thick prism n_0, n_1, and n_2, and primed angles \theta' indicate the ray's angle after refraction.
Ray angle deviation and dispersion through a prism can be determined by
tracing a sample ray through the element and using
Snell's law at each interface. For the prism shown at right, the indicated angles are given by :\begin{align} \theta'_0 &= \, \text{arcsin} \Big( \frac{n_0}{n_1} \, \sin \theta_0 \Big) \\ \theta_1 &= \alpha - \theta'_0 \\ \theta'_1 &= \, \text{arcsin} \Big( \frac{n_1}{n_2} \, \sin \theta_1 \Big) \\ \theta_2 &= \theta'_1 - \alpha \end{align}. All angles are positive in the direction shown in the image. For a prism in air n_0=n_2 \simeq 1. Defining n=n_1, the deviation angle \delta is given by :\delta = \theta_0 + \theta_2 = \theta_0 + \text{arcsin} \Big( n \, \sin \Big[\alpha - \text{arcsin} \Big( \frac{1}{n} \, \sin \theta_0 \Big) \Big] \Big) - \alpha
Thin prism approximation If the angle of incidence \theta_0 and prism apex angle \alpha are both small, \sin \theta \approx \theta and \text{arcsin} x \approx x if the angles are expressed in
radians. This allows the
nonlinear equation in the deviation angle \delta to be approximated by :\delta \approx \theta_0 - \alpha + \Big( n \, \Big[ \Big(\alpha - \frac{1}{n} \, \theta_0 \Big) \Big] \Big) = \theta_0 - \alpha + n \alpha - \theta_0 = (n - 1) \alpha \ . The deviation angle depends on wavelength through
n, so for a thin prism the deviation angle varies with wavelength according to :\delta (\lambda) \approx [ n (\lambda) - 1 ] \alpha .
Multiple prisms Aligning multiple prisms in series can enhance the dispersion greatly, or vice versa, allow beam manipulation with suppressed dispersion. As shown above, the dispersive behaviour of each prism depends strongly on the angle of incidence, which is determined by the presence of surrounding prisms. Therefore, the resulting dispersion is not a simple sum of individual contributions (unless all prisms can be approximated as thin ones). == Choice of optical material for optimum dispersion ==