An electrically conductive silver-polyacrylamide-alginate hydrogel composite for soft electronics

Hydrogels offer tissue-like compliance, stretchability, fracture toughness, ionic conductivity and compatibility with biological tissues. However, their electrical conductivity (<100 S cm(-1)) is inadequate for digital circuits and applications in bioelectronics. Furthermore, efforts to increase conductivity by using hydrogel composites with conductive fillers have led to compromises in compliance and deformability. Here, we report a hydrogel composite that has a high electrical conductivity (>350 S cm(-1)) and is capable of delivering direct current while maintaining soft compliance (Young's modulus < 1 kPa) and deformability. Micrometre-sized silver flakes are suspended in a polyacrylamide-alginate hydrogel matrix and, after going through a partial dehydration process, the flakes form percolating networks that are electrically conductive and robust to mechanical deformations. To illustrate the capabilities of our silver-hydrogel composite, we use the material in a stingray-inspired swimmer and a neuromuscular electrical stimulation electrode. A hydrogel composite that consists of micrometre-sized silver flakes suspended in a polyacrylamide-alginate hydrogel matrix exhibits a high electrical conductivity of over 350 S cm(-1) and a low Young's modulus of less than 10 kPa.

Automated summary

The silver-hydrogel composite exhibits a high electrical conductivity of over 350 S cm(-1) and a low Young's modulus of less than 10 kPa. It demonstrates soft compliance and deformability, making it suitable for various applications such as stingray-inspired swimmers and neuromuscular electrical stimulation electrodes.