Fabricating optical interconnects with polymer materials

Wednesday, 20 April, 2022

Fabricating optical interconnects with polymer materials

Researchers from the University of Arizona have developed new polymer materials that are ideal for making the optical links necessary to connect chip-based photonic components with board-level circuits or optical fibres.

Described in the journal Optical Materials Express, the polymers can be used to easily create interconnects between photonic chips and optical printed circuit boards, the light-based equivalent of electronic printed circuit boards.

“These new materials and the processes they enable could lead to powerful new photonic modules based on silicon photonics,” said research team leader Robert Norwood. “They could also be useful for optical sensing or making holographic displays for augmented and virtual reality applications.”

Silicon photonics technology allows light-based components to be integrated onto a tiny chip. Although many of the basic building blocks of silicon photonic devices have been demonstrated, better methods are needed to fabricate the optical connections that link these components together to make more complex systems.

The researchers developed new polymer materials that feature a refractive index that can be adjusted with ultraviolet (UV) light and low optical losses. These materials allow a single-mode optical interconnect to be printed directly into a dry film material using a low-cost, high-throughput lithography system that is compatible with the CMOS manufacturing techniques used to make chip-based photonic components.

“This technology makes it more practical to fabricate optical interconnects, which can be used to make the internet — especially the data centres that make it run — more efficient,” Norwood said. “Compared to their electronic counterparts, optical interconnects can increase data throughput while also generating less heat. This reduces power consumption and cooling requirements.”

Replacing wires with light

The research expands on a vinylthiophenol polymer material system known as S-BOC that the investigators developed previously. This material has a refractive index that can be modified using UV illumination. In the new work, the researchers partially fluorinated S-BOC to improve its light efficiency. The new material system, called FS-BOC, exhibits lower optical propagation losses than many other optical interconnect materials.

“With this material we can use a process that we call SmartPrint to directly write optical interconnections between different optical printed circuit board elements, such as ion-exchange (IOX) glass waveguides provided by our collaborator Lars Brusberg from Corning Incorporated,” Norwood said.

To perform the SmartPrint process, an FS-BOC film is applied directly to a photonic component. No mechanical alignment is needed, as the optical interconnect is made using a maskless lithography system that calculates where the interconnect is required by looking at the components and then writing the optical interconnect into the polymer using photoexposure. No additional processing is necessary, other than briefly heating the polymer film to 90°C. Because the fabrication approach is maskless, writing patterns can be changed without making a new photomask.

Creating a connection

To demonstrate the new materials, the researchers deposited them directly onto ion-exchange glass waveguide arrays, which are commonly used for integrated photonic devices. They then printed the coupling features needed to allow light to travel out of one IOX waveguide, propagate into the newly fabricated polymer interconnect and then enter a second IOX waveguide adjacent to the initial IOX waveguide.

According to the researchers, the polymer optical interconnects worked well and showed low propagation and coupling losses, which means very little light was lost as it travelled within the interconnect or between it and the other components. The researchers are now working to improve the material’s refractive index contrast and performance at high temperatures.

“A higher refractive index contrast would make the material more tolerant to manufacturing variations, while high-temperature performance is likely needed for the interconnect to withstand solder reflow processes which take place above 200°C,” Norwood said.

Image credit: ©stock.adobe.com/au/Maxim_Kazmin

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