Novel Antireflection Film To Maximize Transmission Of Infrared Light

A research team from the Hefei Institutes of Physical Science (HFIPS) of the Chinese Academy of Sciences (CAS) recently prepared infrared antireflective films by sol-gel method basing on infrared substrate.

High refractive index of the substrate material often leads to serious reflection on the surface of infrared optical elements, which will greatly reduce the transmittance of infrared light. To maximize the transmission of infrared light, antireflection (AR) film needs to be plated on the surface of infrared substrate. Sol-gel technology is an effective method for preparing high temperature resistant film.

At present, there have been many reports on the preparation of AR film in visible light, however, it is still a challenge to prepare AR film working in infrared band by sol-gel method.

"What we made is two band double-layer infrared AR film coating on cadmium selenide (CdSe) substrate," said XU Shaohui, first author of the study, "thick infrared film is usually not resistant to high temperature annealing, and we have solved this problem by reasonably designing the sol composition and adding additives."

The pore size and particle size of the film is uniform and small, which effectively avoid light scattering. After coating, the reflection can be reduced simultaneously at 2 μm and 2.5 μm, and the reflectivity is 2.1% and 2.8%, respectively.

At the same time, the film can reduce reflection in a wide band, the average reflectivity in 1.8-2.6 μm is 2.6%, which is 27% lower than that of the uncoated sample. The AR film remains intact after 10 cold and thermal shocks at high temperature of 400 °C and low temperature of -16 °C.

"It shows good high and low temperature resistance," said XU.

This work is very important for further understanding the effects of additives and film structure on thermal stability. It provides valuable guidance for preparing long wavelength AR coating by sol-gel method, which is helpful to promote the development of infrared optical films.

Relevant research results were published on Colloids and Surfaces A: Physicochemical and Engineering Aspects.