Photolithography-Based Microfabrication of Biodegradable Flexible and Stretchable Sensors

Biodegradable sensors based on integrating conductive layers with polymeric materials in flexible and stretchable forms have been established. However, the lack of a generalized microfabrication method results in large-sized, low spatial density, and low device yield compared to the silicon-based devices manufactured via batch-compatible microfabrication processes. Here, a batch fabrication-compatible photolithography-based microfabrication approach for biodegradable and highly miniaturized essential sensor components is presented on flexible and stretchable substrates. Up to 1600 devices are fabricated within a 1 cm(2) footprint and then the functionality of various biodegradable passive electrical components, mechanical sensors, and chemical sensors is demonstrated on flexible and stretchable substrates. The results are highly repeatable and consistent, proving the proposed method's high device yield and high-density potential. This simple, innovative, and robust fabrication recipe allows complete freedom over the applicability of various biodegradable materials with different properties toward the unique application of interests. The process offers a route to utilize standard micro-fabrication procedures toward scalable fabrication of highly miniaturized flexible and stretchable transient sensors and electronics.

Automated summary

Biodegradable sensors based on integrating conductive layers with polymeric materials in flexible and stretchable forms have been successfully fabricated using a photolithography-based microfabrication approach. Up to 1600 devices with high device yield and density are fabricated on flexible and stretchable substrates. Various biodegradable passive electrical components, mechanical sensors, and chemical sensors have been demonstrated on these substrates, proving the versatility and scalability of the proposed fabrication method.