List of coating design exapmles

Antireflection

• Broadband Antireflection Graded-Index Coating
• Growing an Antireflection Coating
• Broadband AR for a Cone of Light

Beamsplitter

• New Thin Film Polarizing Beamsplitter
• Immersed Wide-Angle Polarizer
• Immersed Wideband Nonpolarizing Beamsplitter
• Symmetric Immersed Beamsplitter
• Nonpolarizing Beamsplitter for OIC Contest

Reflector

• Extreme Ultraviolet Mirrors
• Dielectric Omnidirectional Reflector
• Broadband High-Reflection Coating at 50 Degrees
• Cold Mirror

Bandpass

• Wide Infrared Bandpass Filter
• Metal-Dielectric Dual Bandpass Filter
• Metal-Dielectric Bandpass Filter
• Family of WDM and DWDM Filters
• 8-Skip-0 WDM Filters
• Four-Wavelength Bandpass Filter
• Triple Bandpass Filter for OIC Contest

Miscellaneous

• Transparent Metal Coatings
• Fabry-Perot Interferometer Coating
• Dielectric Sunglasses
• Photopic Filter

Nonpolarizing Beamsplitter for OIC Contest

Every three years the OSA (Optical Society of America) holds a meeting called OIC (Optical Interference Coatings). As part of that meeting, there is always a design contest. The 2007 meeting has two design problems, the second of which is discussed here. The first problem is a Triple Bandpass Filter.

The challenge is to design a 45ｰ beamsplitter on a glass (index 1.52) substrate. The incident and exit mediums are air. Only the front side of the substrate needs a coating; we can assume the back side has a perfect AR coating. For a wavelength range as wide as possible, and centered at 550 nm, the beamsplitter design has the following performance requirements:

• | Rs – Rp | ≤ 2%
• 40% ≤ Rs ≤ 60%
• 40% ≤ Rp ≤ 60%
• | δRs – δRp | ≤ 1ｰ (difference of p and s reflected phase, Abeles convention)
• | δTs – δTp | ≤ 1ｰ (difference of p and s transmitted phase)

The coating design may use a maximum of three materials from the following list of seven indices: 1.38, 1.45, 1.65, 1.8, 2.05, 2.2, and 2.35. The materials are assumed to be dielectric and non-dispersive. There is no limit on the number of layers. However, layers are required to be at least 5 nm thick. The design is to be evaluated every 0.001 nm to ensure that all requirements are met. The winning design is the one that meets the requirements for the widest wavelength range centered at 550 nm.

The above requirements can be translated into seven continuous optimization targets. We give the first five targets more weight than the last two phase targets because it is best to meet the reflectance targets before worrying about phase. An important decision is the selection of the three coating materials. There are a total of 35 combinations of seven materials. Experience suggests that the three indices should be as widely separated as possible. Three good possibilities are the sets (1.38, 1.65, 2.35), (1.38, 1.8, 2.35), and (1.38, 1.65, 2.2).

Some experimenting finds that the indices (1.38, 1.65, 2.2) appear to work best, giving widest possible bandwidth of about 30 nm: 535 to 565 nm. As the bandwidth is increased, it becomes more difficult to keep both the reflectance and the phase differences within their required ranges.

In all of our designs, we start with a single thin layer and use TFCalc’s needle/tunneling optimization to design the beamsplitter from “scratch”. The plots below show the performance. Note that the phase differences are split across the last two plots.