Technique bonds copper foil and PTFE for better 5G

Technique bonds copper foil and PTFE for better 5G

Business news |
By Jean-Pierre Joosting

Researchers from Osaka University have demonstrated a method for strongly combining polytetrafluoroethylene (PTFE) and smooth copper foil. As communication systems become increasingly complex and and higher frequency bands come into use, the loss of transmission from the conduction component of the circuit becomes more critical. Consequently, materials must be continually improved to create future-ready printed wiring boards (PWBs).

Copper is the go-to wiring material for PWBs because it is highly conductive, and thus efficiently transports information to its destination. There is currently nothing superior to copper for this task, so the focus for improvement is to decrease transmission loss from the support material.

PTFE is ideal for this role because it has both low relative dielectric constant and low dielectric loss tangent. However, PTFE does not like to stick to things. An intermediate layer is often used between PTFE and copper to improve the adhesion, but using these layers is a tradeoff because they increase insertion losses.

In this study, the researchers have created an adhesive-free method of sticking commercially available PTFE to copper foil with high adhesion strength, thus dispensing with the need for a middle layer.

“Our technique involves what is known as heat-assisted plasma (HAP) treatment,” explains first author Misa Nishino. “We subjected the PTFE to a HAP to make the surface stickier, and then pressed the two layers together at a high temperature to ensure they were strongly bonded.”

Comparison of the developed printed circuit board and conventional alternatives. Credit: M. Nishino et al.

The research team examined pure PTFE and a cloth woven from glass and PTFE and found that both showed significantly increased adhesion to copper foil after HAP treatment. In addition, the very smooth surface of the copper foil meant that the transmission could have an obstruction free pathway, minimizing the losses.

“Our method is both simple and environmentally friendly, making it a highly attractive option for large scale processes,” says study corresponding author Yuji Ohkubo. “We expect our findings will be used to make high-frequency PWBs that will contribute to the enhancement of digital devices for the 5G world and beyond.”

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