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Full-Text Articles in Physics
Finite-Difference Time-Domain Simulation Of A Liquid-Crystal Optical Phased Array, Xinghua Wang, Bin Wang, Philip Bos, James E. Anderson, John J. Pouch, Felix A. Miranda
Finite-Difference Time-Domain Simulation Of A Liquid-Crystal Optical Phased Array, Xinghua Wang, Bin Wang, Philip Bos, James E. Anderson, John J. Pouch, Felix A. Miranda
Philip J. Bos
Accurate modeling of a high-resolution, liquid-crystal-based, optical phased array (OPA) is demonstrated. The modeling method is extendable to cases where the array element size is close to the wavelength of light. This is accomplished through calculating an equilibrium liquid-crystal (LC) director field that takes into account the fringing electric fields in LC OPAs with small array elements and by calculating the light transmission with a finite-difference time-domain method that has been extended for use in birefringent materials. The diffraction efficiency for a test device is calculated and compared with the simulation.
Light Propagation In Variable-Refractive-Index Materials With Liquid-Crystal-Infiltrated Microcavities, Bin Wang, Philip Bos, Charles D. Hoke
Light Propagation In Variable-Refractive-Index Materials With Liquid-Crystal-Infiltrated Microcavities, Bin Wang, Philip Bos, Charles D. Hoke
Philip J. Bos
A liquid-crystal-infiltrated microcavity structure is proposed as a variable-refractive-index material. It has the advantages over previously considered nanostructured materials of having a larger phase-angle change and lower driving voltage. Two-dimensional liquid-crystal director and finite-difference time-domain optical simulations are used to select liquid crystal material parameters and optimize the dimension of the microcavity structured material.