If a phone or other electronic device was made of soft materials, how would that change its use? Would it be more durable? If hospital health monitoring equipment was made of less rigid components, would it make it easier for patients to wear?
While electronics of that type may still be far in the future, Virginia Tech researchers have developed an innovative method for constructing the soft electronic components that make them up. The focus of a project from the team of Michael Bartlett, principal investigator and associate professor in the Department of Mechanical Engineering, is on the circuits that manage all the electronic connections inside.
“This brings us closer to exciting possibilities like advanced soft robotics, wearable devices, and electronics that can stretch, bend, and twist while maintaining high functionality,” Bartlett said.
The work was supported by Bartlett’s Office of Naval Research Young Investigator Program award and National Science Foundation Early Faculty Career Development (CAREER) award, as well as support from Virginia Tech.
Soft electronics, vias, and interconnects
Previous soft circuit research developed by Bartlett’s team replaces inflexible materials with soft electronic composites and tiny, electricity-conducting liquid metal droplets. These soft electronics are part of a rapidly emerging field of technology that give gadgets a new level of durability.
In this project, researchers took on the problem of soft circuit boards, particularly the passing of electrical currents between the layers that stack on top of one another. This is important to make good use of electrical current in the tight space circuit boards occupy.
Whereas conventional rigid electronics utilize well-established techniques for creating vias, which are essential to make the multilayer electronics that are common today, they often require holes be drilled through a circuit board, which works when rigid materials are used to connect those layers. In a flexible material where a punched hole might stretch open, controlling that current requires a different approach.
The team’s new technique makes no holes and uses liquid metal microdroplets to form soft vias and planar interconnects, creating electrical connections through and across circuit layers, overcoming these challenges. The process involves the directed stratification of liquid metal droplets within a photoresin. By leveraging irregularities that arise during ultraviolet exposure, the researchers create a stair-like structure that allows the droplets to controllably assemble in 3D.
This approach is highly versatile, and these liquid metal vias and interconnects can be implemented in several types of materials. They can go further and perform the fabrication approach multiple times and create more and more layers.
link
More Stories
Exponential Growth Predicted for The Flexible Electronics
Graphene technique improves ultrathin film manufacturing for flexible electronics
Flexible electronics integrated with paper-thin structure for use in space