Kinetics of photoinduced anisotropy in azopolymers: models and mechanisms

TL;DR

This paper presents a comprehensive phenomenological model for photoinduced optical anisotropy in azopolymers, accounting for various mechanisms, stability, and experimental validation, advancing understanding of POA dynamics.

Contribution

It introduces a unified, tractable model for POA kinetics in azopolymers, incorporating biaxiality and long-term stability, and distinguishes mechanisms based on light wavelength.

Findings

Model accurately predicts absorption coefficient dependencies on illumination time.

Different POA mechanisms dominate depending on the pumping light wavelength.

Numerical results align well with experimental data.

Abstract

We consider the effect of photoinduced optical anisotropy (POA) in azopolymers. Using a unified approach to the kinetics of photo-reorientation we discuss the assumptions underlying the known theoretical models of POA and formulate a tractable phenomenological model in terms of angular redistribution probabilities and order parameter correlation functions. The model takes into account biaxiality effects and long term stability of POA in azopolymers. It predicts that under certain conditions two different mechanisms, photoorientation and photoselection, will dominate POA depending on the wavelength of pumping light. By using available experimental data, we employ the model to compute dependencies of principal absorption coefficients on the illumination time. Our calculations clearly indicate the different regimes of POA and the numerical results are found to be in good agreement with the experimental data.