Analysis of Nonlinear Random Polarization in Dispersive Dielectrics

We present a study on the time-domain propagation of electromagnetic waves in dielectric materials modeled by a nonlinear Debye medium with random perturbations.

Polynomial Chaos Expansions are employed to transform the random nonlinear Debye polarization model into a deterministic framework.

We extend the Yee discretization to the resulting coupled system, establish second order accuracy, and verify convergence numerically.

We investigate the sensitivity of nonlinear properties to uncertainty, particularly when the amplitude of the input signal is large.

Given the challenges in manufacturing where uncertainties can cause optimal parameters to vary and potentially disrupt nonlinear effects, our approach incorporates these uncertainties within the simulation.

This can enable the model-based design identification of realizable materials that maintain their desired effects despite variations.

The findings from this study contribute to a deeper understanding of wave propagation in complex media, with potential implications for applications in optical communications, material science, and electromagnetic wave control.