3D Switchable Diffractive Optical Elements Fabricated with Two-Photon Polymerization

Direct laser writing is demonstrated by two-photon polymerization of multi-element diffractive optical components that can be switched on and off with an applied voltage. By exploiting the 3D capabilities of the laser microfabrication technique, multiple diffractive optical elements are written into a single liquid crystal (LC) layer. The switching behavior of the diffractive optical elements is controlled by simply changing the write-voltage of the anisotropic polymer structures during fabrication. Initially, 2D diffraction gratings are written at different depths within the LC layer. Each element is then activated by applying a voltage of sufficient amplitude that causes the second diffractive optical element to become inactive. This is then followed by a demonstration of multi-element computer generated holograms that are written at different depths within the LC layer. By altering the magnitude of the applied voltage, different images/patterns can be observed in the replay field using a simple electrode configuration. These compact and transmissive LC optical components could excel in applications where a degree of switchability is required but a highly pixelated fully programmable device is excessive.

Automated summary

Direct laser writing of multi-element diffractive optical components using two-photon polymerization is demonstrated in this study. The components can be switched on and off with an applied voltage. By utilizing the 3D capabilities of the laser microfabrication technique, multiple elements are written into a single liquid crystal layer. The switching behavior of the elements is controlled by changing the write-voltage during fabrication. These compact and transmissive optical components show great potential in applications that require switchability.