We study the enhancement and control of the refractive index of liquid crystals with
dispersed gold and silver nanoparticles. The maximum obtainable variation in the real
and imaginary parts of the effective refractive index of the solution by reorientation of
the liquid crystal molecules is calculated, and the results obtained with gold and silver
nanospheres are compared. The effect of size, concentration, and composition of the
nano-particulates (solid spheres vs. silver- or gold-coated silica nanoshells) on the
refractive index and its wavelength dependence is also considered.
We present a theoretical model and some experiment demonstrations of all-optical passive switching processes with 90°
twist-aligned nano-doped nematic liquid crystal cells sandwiched between two crossed polarizers. The photosensitive
dopants give rise to laser induced dye-assisted director axis reorientation and order parameter modifications, which in
turn produce an intensity dependent polarization switching and hence a transmission modulation capability.
Experimental observations are in good agreement with our expectation derived from modified Jones matrix analysis and
also demonstrate the feasibility of an efficient [microwatt power] low threshold polarization and fast switching
[microseconds] all optical limiting device for visible as well as infrared lasers or bright light sources.
Stimulated Orientational Scattering (SOS) uses the angular reorientation of the director axis in liquid crystals to produce
cross-polarized light amplification. Akin to photorefractivity, SOS uses grating formation and the resulting phase-matching
to scatter incident radiation into a coherent, cross-polarized signal beam. This paper provides a brief review of
the theory underlying SOS, a discussion of the simulation of SOS dynamics, and empirical results of the SOS effect
acting in a thin film (300 μm) planar sample of the liquid crystal E7 induced by an Argon ion laser at a wavelength of