Polarization gratings in the short-pitch approximation: electro-optics of deformed helix ferroelectric liquid crystals

TL;DR

This paper develops a theoretical model for the electro-optical behavior of deformed helix ferroelectric liquid crystal cells using polarization gratings, and validates it with experimental data, revealing voltage-controlled optical properties.

Contribution

It introduces a comprehensive theoretical approach relating diffraction matrices to Floquet harmonics for DHFLCs in the short-pitch approximation, and compares predictions with experiments.

Findings

The model accurately predicts transmittance as a function of voltage.

DHFLCs behave as biaxial layers with voltage-dependent optical axes.

Good agreement between theory and experimental transmittance curves.

Abstract

Electro-optical properties of deformed helix ferroelectric liquid crystal (DHFLC) cells are studied by using a general theoretical approach to polarization gratings in which the transmission and reflection matrices of diffraction orders are explicitly related to the evolution operator of equations for the Floquet harmonics. In the short-pitch approximation, a DHFLC cell is shown to be optically equivalent to a uniformly anisotropic biaxial layer where one of the optical axes is normal to the substrates. For in-plane anisotropy, orientation of the optical axes and birefringence are both determined by the voltage applied across the cell and represent the parameters that govern the transmittance of normally incident light passing through crossed polarizers. We calculate the transmittance as a function of the applied voltage and compare the computed curves with the experimental data. The theoretical and experimental results are found to be in good agreement.